SPIE Medical Imaging 50th anniversary: history of the Picture Archiving and Communication Systems Conference

Katherine P Andriole

doi:10.1117/1.JMI.9.S1.S12210

. 2022 Oct 12;9(Suppl 1):S12210. doi: 10.1117/1.JMI.9.S1.S12210

SPIE Medical Imaging 50th anniversary: history of the Picture Archiving and Communication Systems Conference

Katherine P Andriole ^1,^*

PMCID: PMC9558896 PMID: 36259081

Abstract.

To commemorate the SPIE Medical Imaging 50th anniversary, this article provides a brief review of the Picture Archiving and Communication Systems (PACS) and Informatics conferences. Important topics and advances, contributing researchers from both academia and industry, and key papers are noted.

Keywords: PACS, archives, networks, displays, standards, imaging informatics, technology impact, cost assessment

1. Introduction

Picture archiving and communication systems (PACS) and imaging informatics have been topics covered in forty of the past fifty years of the SPIE Medical Imaging symposium. PACS or medical image management systems were developed to electronically acquire, archive, transmit, and display medical images, providing cost-effective storage and retrieval of radiologic examinations, and simultaneous access to studies from multiple locations. PACS ultimately enabled the transition of medical imaging, and radiology in particular, from an analog film-based operation to a digital workflow. The resulting treasure troves of digital medical images are now accessible from secure cloud storage devices over ubiquitous reliable networks and can be viewed on inexpensive electronic display devices. With the use of today’s highly performant computer graphics processing units (GPUs), computer image processing and analysis algorithms and machine and deep learning applications can be translated from the research laboratory to the clinical arena.

Initial concepts for PACS were introduced at the 1981 SPIE “First International Conference and Workshop on PACS” and presented papers were published in a proceedings in 1982. The PACS conference name has been modified multiple times over the years to reflect the important research activities of the period (Table 1), and some previously covered topics were moved to other newly formed SPIE Medical Imaging conferences, such as Image Perception, Computer-Aided Diagnosis, and Digital Pathology, as paper submissions in those areas increased.

Table 1.

PACS Conference names, year, volume number, location, conference co-chairs, and number of papers. PACS-specific conference titles appear in bold; italic titles denote a name change (PACS: Picture Archiving and Communication Systems).

Year	Volume	Location	Conference name	Co-chairs	# of papers
1981	0318	Newport Beach, CA	*1st International Conference and Workshop on PACS*	Andre J. Duerinckx	83
1982	0372	Pacific Grove, CA	Intl. Workshop on Physics and Engineering in Medical Imaging	Orhan Nalcioglu	40
1983	0418	Kansas City, KS	PACS II	Samuel J. Dwyer III	45
1984	0486	Las Vegas, NV	Medical Imaging and Instrumentation ‘84	James A. Mulvaney	32
1984	0515	Arlington, VA	Medical Images and Icons	Andre J. Duerinckx, Murray H. Loew, Judith M.S. Prewitt	64
1985	0536	California	3rd Intl Conference on PACS	Samuel J. Dwyer III, Robert J. Schneider	34
1985	0555	Boston, MA	Medical Imaging and Instrumentation ‘85	James A. Mulvaney	36
1986	0671	Newport Beach, CA	Physics and Engineering of Computerized Multidimensional Imaging and Processing	Thomas F. Budinger, Zang-Hee Cho, Orhan Nalcioglu	43
1987	0767	Newport Beach CA	Medical Imaging I	Samuel J. Dwyer III, Roger H. Schneider	55
1988	0914	Newport Beach CA	Medical Imaging II	Samuel J. Dwyer III, Roger H. Schneider	188
1989	1093	Newport Beach CA	Medical Imaging III: PACS System Design and Evaluation	Samuel J. Dwyer III, R. Gilbert Jost, Roger H. Schneider	69
1990	1234	Newport Beach, CA	Medical Imaging IV: PACS System Design and Evaluation	Samuel J. Dwyer III, R. Gilbert Jost	113
1991	1446	San Jose, CA	Medical Imaging V: PACS Design and Evaluation	Samuel J. Dwyer III, R. Gilbert Jost	57
1992	1654	Newport Beach, CA	Medical Imaging VI: PACS Design and Evaluation	R. Gilbert Jost	69
1993	1899	Newport Beach, CA	Medical Imaging 1993: PACS Design and Evaluation	R. Gilbert Jost	68
1994	2165	Newport Beach, CA	Medical Imaging 1994: PACS Design and Evaluation	R. Gilbert Jost	97
1995	2435	San Diego, CA	Medical Imaging 1995: PACS Design and Evaluation: Engineering and Clinical Issues	R. Gilbert Jost, Samuel J. Dwyer III	67
1996	2711	Newport Beach, CA	Medical Imaging 1996: PACS Design and Evaluation: Engineering and Clinical Issues	R. Gilbert Jost, Samuel J. Dwyer III	66
1997	3035	Newport Beach, CA	Medical Imaging 1997: PACS Design and Evaluation: Engineering and Clinical Issues	Steven C. Horii, G. James Blaine	78
1998	3339	San Diego, CA	Medical Imaging 1998: PACS Design and Evaluation: Engineering and Clinical Issues	Steven C. Horii, G. James Blaine	65
1999	3662	San Diego, CA	Medical Imaging 1999: PACS Design and Evaluation: Engineering and Clinical Issues	G. James Blaine, Steven C. Horii	52
2000	3980	San Diego, CA	Medical Imaging 2000: PACS Design and Evaluation: Engineering and Clinical Issues	G. James Blaine, Eliot L. Siegel	55
2001	4323	San Diego, CA	Medical Imaging 2001: PACS and Integrated Medical Information Systems: Design and Evaluation	Eliot L. Siegel, H. K. Huang	56
2002	4685	San Diego, CA	Medical Imaging 2002: PACS and Integrated Medical Information Systems: Design and Evaluation	Eliot L. Siegel, H. K. Huang	54
2003	5033	San Diego, CA	Medical Imaging 2003: PACS and Integrated Medical Information Systems: Design and Evaluation	H. K. Huang, Osman M. Ratib	57
2004	5371	San Diego, CA	Medical Imaging 2004: PACS and Imaging Informatics	Osman M. Ratib, H. K. Huang	48
2005	5748	San Diego, CA	Medical Imaging 2005: PACS and Imaging Informatics	Osman M. Ratib, Steven C. Horii	63
2006	6145	San Diego, CA	Medical Imaging 2006: PACS and Imaging Informatics	Steven C. Horii, Osman M. Ratib	43
2007	6516	San Diego, CA	Medical Imaging 2007: PACS and Imaging Informatics	Steven C. Horii, Katherine P. Andriole	50
2008	6919	San Diego, CA	Medical Imaging 2008: PACS and Imaging Informatics	Katherine P. Andriole, Khan M. Siddiqui	43
2009	7264	Lake Buena Vista, FL	Medical Imaging 2009: Advanced PACS-based Imaging Informatics and Therapeutic Applications	Khan M. Siddiqui, Brent J. Liu	36
2010	7628	San Diego, CA	Medical Imaging 2010: Advanced PACS-based Imaging Informatics and Therapeutic Applications	Brent J. Liu, William W. Boonn	38
2011	7967	Lake Buena Vista, FL	Medical Imaging 2011: Advanced PACS-based Imaging Informatics and Therapeutic Applications	William W. Boonn, Brent J. Liu	36
2012	8319	San Diego, CA	Medical Imaging 2012: Advanced PACS-based Imaging Informatics and Therapeutic Applications	William W. Boonn, Brent J. Liu	34
2013	8674	Lake Buena Vista, FL	Medical Imaging 2013: Advanced PACS-based Imaging Informatics and Therapeutic Applications	Maria Y. Law, William W. Boonn	32
2014	9039	San Diego, CA	Medical Imaging 2014: PACS and Imaging Informatics: Next Generation and Innovations	Maria Y. Law, Tessa S. Cook	29
2015	9418	Orlando, FL	Medical Imaging 2015: PACS and Imaging Informatics: Next Generation and Innovations	Tessa S. Cook, Jianguo Zhang	37
2016	9789	San Diego, CA	Medical Imaging 2016: PACS and Imaging Informatics: Next Generation and Innovations	Jianguo Zhang, Tessa S. Cook	32
2017	10138	Orlando, FL	Medical Imaging 2017: Imaging Informatics for Healthcare, Research and Applications	Tessa S. Cook, Jianguo Zhang	41
2018	10579	Houston, TX	Medical Imaging 2018: Imaging Informatics for Healthcare, Research and Applications	Jianguo Zhang, Po-Hao Chen	58
2019	10954	San Diego, CA	Medical Imaging 2019: Imaging Informatics for Healthcare, Research and Applications	Po-Hao Chen, Peter R. Bak	48
2020	11318	Houston, TX	Medical Imaging 2020: Imaging Informatics for Healthcare, Research and Applications	Po-Hao Chen, Thomas M. Deserno	45
2021	11601	Virtual Online	Medical Imaging 2021: Imaging Informatics for Healthcare, Research and Applications	Thomas M. Deserno, Brian J. Park	32
2022	12037	San Diego and Podcast	Medical Imaging 2022: Imaging Informatics for Healthcare, Research and Applications	Thomas M. Deserno, Brian J. Park	32
2022	12037	San Diego and Podcast		Thomas M. Deserno, Brian J. Park	8

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The SPIE Medical Imaging symposia have been excellent forums for commingling of academic and industry researchers, while also providing a suitable environment at which students, postdoctoral fellows, and junior faculty could present their first research paper or poster. For the first decade of SPIE Medical Imaging PACS meetings, the conference proceedings were one of the few scientific venues in which to publish PACS and imaging informatics research.

This article reviews the forty-year history of the PACS and Imaging Informatics conferences as part of the SPIE Medical Imaging symposia. Important topics and advances are highlighted, and contributing researchers from both academia and industry are noted along with key research papers.

2. 1980’s PACS Conferences

2.1. 1981

Andre J. Duerinckx (Philips Ultrasound, Inc) chaired the “ First International Conference and Workshop on PACS” held in January of 1981 at Newport Beach, California. Eighty-three papers were presented and subsequently published in a proceedings in January 1982. Multiple papers included PACS concept descriptions and prototype architectures including accounts by Dwyer and Templeton (University of Kansas),¹^,² Duerinckx (Philips Ultrasound, Inc.),³ Vizy (Eastman Kodak),⁴ Staab (University of North Carolina),⁵ Bohm (Institut fur Mathematik and Datenverarbeitung in der Medizin, Germany),⁶ and Blaine and Jost (Washing University St Louis).⁷ Horii (New York University) discussed the cost of PACS,⁸ and Arenson (University of Pennsylvania) detailed radiology information system management⁹ and fiber optic networks for data communication.¹⁰ Skinner (MITRE Corporation) described technologies for teleradiology.¹¹ Blom (Philips Labs, US)¹² and Billingsley (Jet Propulsion Lab)¹³ reported on optical disc and magnetic tape storage, respectively. Schneider (Food and Drug Administration)¹⁴ and Prewitt (National Institutes of Health)¹⁵ discussed the need for standards prior to the formation of the ACR-NEMA (American College of Radiology-National Electronic Manufacturers Association) committee which ultimately evolved into the Digital Imaging and Communications in Medicine (DICOM) standards committee. Other topics appearing in the first PACS conference included two papers on perception, three covering legal aspects of PACS, and six described modality mini-PACS. Figure 1 (top) shows the distribution of topics presented at the first PACS conference in 1991. In addition to paper presentations, two workshops were held including a panel of equipment manufacturers who presented their views on PACS¹⁶ and a panel representing the medical community’s view on PACS.¹⁷ The above authors and their home institutions representing academia and industry, US and international researchers, were among the early PACS pioneers.

Fig. 1 — Distribution of topics presented at the 1982 PACS conference (top) and the sum of topics presented during the 1980 meetings (bottom). The last eight topics to the right (horizontal line fill) are new topics from year one.

2.2. 1982

No PACS-specific conference was held in 1982 but the “International Workshop on Physics and Engineering in Medical Imaging” was held in Pacific Grove, California, and chaired by Orhan Nalcioglu. Several papers covered digital projection radiography.¹⁸

2.3. 1983

“Picture Archiving and Communication Systems (PACS II)” was held in Kansas City, Kansas, and chaired by Samuel J. Dwyer III. Many papers presented general PACS concepts¹⁹^–²⁴ with some focusing on the display piece with observations that better functionality was required to move PACS forward.²⁵^–²⁹ The importance of databases³⁰^,³¹ and radiology information system (RIS) functionality were noted as well as the need for standards³²^,³³ and studies of image quality.³⁴ Networking,³⁵^,³⁶ storage media³⁷^–³⁹ and the use of compression⁴⁰^,⁴¹ were included. H.K. Huang’s laboratory (UCLA) presented multiple papers on PACS design and implementation.⁴²

2.4. 1984

The next PACS-specific conference was not held until 1985 but two other relevant conferences had active participation. The “Medical Imaging and Instrumentation ‘84” conference chaired by James A. Mulvaney was held in Las Vegas, Nevada, in April and the “Medical Images and Icons” chaired by Andre J. Duerinckx, Murray H. Loew and Judith MS Prewitt was held in Arlington, Virginia, in July. Digital projection radiography⁴³^,⁴⁴ and digital image display quality⁴⁵^–⁵⁶ were several of the topics addressed at the “Medical Imaging and Instrumentation” meeting. At the “Medical Images and Icons” conference, image processing papers appeared prominently, as did image display including 3D,⁴⁷^–⁴⁹ PACS design concepts,⁵⁰^–⁵⁴ image acquisition,⁵⁵^,⁵⁶ standards,⁵⁷ display design,⁵⁸^–⁶⁰ and networking.⁶¹ A paper on archival media that described an optical disk that could store 15,000 CT images⁶² was presented. Commercial challenges for PACS were reported on,⁶³ and several mini-PACS including for pathology images were discussed.⁶⁴^,⁶⁵ One paper used artificial intelligence for image understanding.⁶⁶

2.5. 1985

The “Third International Conference on Picture Archiving and Communication Systems” was chaired by Samuel J. Dwyer III and Robert J. Schneider. At this meeting the ACR-NEMA digital imaging interface standard was first mentioned in two papers.⁶⁷^,⁶⁸ Sam Dwyer presented his seminal work on archival requirements that led to the concept of a hierarchical storage management schema.⁶⁹ Networking,⁷⁰ image data compression,⁷¹^,⁷² and design considerations for image display⁷³^–⁷⁸^,⁷⁸ were topics presented. The importance of inclusion of comparison examinations in PACS displays,⁷⁹ integration of radiology reporting systems,⁸⁰ and integration into clinical workflow,⁸¹ were all mentioned. Examples of PACS at several institutions⁸²^,⁸³ were described along with cost-benefit implications.⁸⁴ Concepts in perception were also presented.⁸⁵ Also held in Boston, Massachusetts, was a “Medical Imaging and Instrumentation” conference that had papers on DICOM⁸⁶ and on PACS design.⁸⁷ Many papers included medical physics assessments of imaging modalities including computed radiography (CR).

2.6. 1986

No specific PACS conference was held in 1986 but the conference on “Physics and Engineering of Computerized Multidimensional Imaging and Processing” was held in Newport Beach, CA. Topics included medical physics of imaging modalities, image reconstruction, image processing, 3D display, and a paper describing the implementation of the AT&T PACS at Duke University Medical Center.⁸⁸

2.7. 1987

The first medical imaging titled conference “Medical Imaging I” chaired by Samuel J. Dwyer III and Roger H. Schneider was held in Newport Beach, California, a recurring location for the SPIE Medical Imaging meetings. Papers on digital projection radiography were prominent. Industry researchers including those from Eastman Kodak,⁸⁹ EI du Pont de Nemours,⁹⁰ and Philips Medical Systems⁹¹ described image quality of computed radiography (CR) (with photostimulable storage phosphor detectors), as did academic researchers.⁹²^,⁹³ Progress for the ACR-NEMA standard was reported,⁹⁴ compression methodologies⁹⁵^,⁹⁶ described, and an algorithm for computerized detection of lung nodules on digital chest radiographs⁹⁷ was presented. Digital image quality assessment and other image processing papers were given.

2.8. 1988

SPIE “Medical Imaging II” had the highest number of papers given (188) of any SPIE PACS conference. It was again chaired by Samuel J. Dwyer III and Roger H. Schneider and held in Newport Beach, California. Multiple papers covered image processing and medical physics topics, particularly image quality comparison of screen/film radiography with CR⁹⁸^–¹⁰² including an ROC (receiver operating characteristic) observer study.¹⁰³ Compression techniques were described,¹⁰⁴^–¹⁰⁶ and digital workstations with comparison to conventional reading including user interface studies were presented.¹⁰⁷^–¹¹⁵ Image networking and transmission studies,¹¹⁶^–¹¹⁸ and PACS technology impact¹¹⁹^–¹²¹ and cost analyses¹²²^,¹²³ papers were presented. Multiple institutions shared their PACS implementation experiences including the University of California at Los Angeles (UCLA), Georgetown University, the University of Pennsylvania, the University of North Carolina at Chapel Hill, Washington University at St. Louis Mallinckrodt Institute, Kyoto University Japan, Victoria Hospital Canada, Toshiba Corporation, and the US Army.¹²⁴^–¹³⁵ The ACR-NEMA Standard Committee that included representatives from academia and industry (eg, Philips Medical Systems; Picker Medical Systems; NEMA; Siemens Medical Systems, US; New York University; Bio-Imaging Research, Inc.; Reality Technologies; Digital Equipment Corp; Veteran’s Administration Medical Center) reported on updates, and implementations using the standard were described.¹³⁶^–¹⁴⁰ Several papers detailed image archiving,¹⁴¹^–¹⁴⁶ and two papers discussed the important concept of interfacing hospital information systems and/or radiology operations/information systems with PACS.¹⁴⁷^,¹⁴⁸

2.9. 1989

Medical Imaging III first used the conference title “PACS System Design and Evaluation” which was used through 1994. Held in Newport Beach, California, the meeting was chaired by Samuel J. Dwyer III, R. Gilbert Jost, and Roger H. Schneider. Architecture descriptions and PACS evaluation papers dominated the meeting,¹⁴⁹^–¹⁶⁵ with a few papers covering archives,¹⁶⁶^–¹⁶⁸ networks¹⁶⁹^–¹⁷¹ and displays.¹⁷²^–¹⁷⁵ Multiple papers described radiology information systems (RIS) and their important link to PACS functionality.¹⁷⁶^–¹⁷⁸ Several papers evaluated cost.¹⁷⁹^–¹⁸⁴ Figure 1 (bottom) shows the distribution of the sum of topics during the 1980s.

3. 1990s PACS Conferences

3.1. 1990

“Medical Imaging IV: PACS Systems Design and Evaluation” was chaired by Samuel J. Dwyer III and R. Gilbert Jost and held again in Newport Beach, California. It had the second largest number of papers at 113. Topics covered cost analysis of film versus PACS workflow,¹⁸⁵ time savings¹⁸⁶ and clinical evaluations,¹⁸⁷^,¹⁸⁸ including image quality assessments.¹⁸⁹^,¹⁹⁰ The notion of multiple types of workstations (diagnostic, clinical review, low-cost) were presented¹⁹¹^–¹⁹³ as were industry efforts¹⁹⁴ and modality mini-PACS.¹⁹⁵^–¹⁹⁷ Network performance including experience with wide-area networks¹⁹⁸ were studied,¹⁹⁹^–²⁰¹ along with archive models.²⁰²^–²⁰⁵ Interfacing RIS-to-PACS for incorporation of clinical history and comparison images were important topics.²⁰⁶^–²⁰⁹

3.2. 1991

Medical Imaging V: “PACS Design and Evaluation” was chaired by Samuel J. Dwyer III and R. Gilbert Jost and held in San Jose, California. Popular paper topics included the use of PACS as “Teleradiology” within a hospital²¹⁰^,²¹¹ including industry collaborations²¹² and reports from Europe.²¹³^,²¹⁴ High-resolution (2K x 2K) display stations were described including for mammography viewing.²¹⁵^,²¹⁶ Fast networks of the time, including those using the ACR/NEMA standard with TCP/IP over ethernet were detailed.²¹⁷^–²¹⁹ PACS reliability issues were discussed and reading times on workstations compared with the film alternator.²²⁰^,²²¹ Hospital information system (HIS)-RIS integration with PACS were again a common theme describing image management optimization.²²²^–²²⁵ Radiologists’ opinions on the use of PACS were studied²²⁶^,²²⁷ and a paper demonstrating a digital radiologic teaching file was presented.²²⁸

3.3. 1992

Medical Imaging VI: “PACS Design and Evaluation” was chaired by R. Gilbert Jost and held in Newport Beach, California. Papers analyzing PACS performance including operations, clinical assessments and user interface optimization at academic hospitals and for military installations were numerous.²²⁹^–²³⁷ Networks were described including use of a dial-up 56Kbit modem,²³⁸ and high-speed technologies were becoming available.²³⁹^–²⁴² Description of other necessary PACS components beyond the display station were presented including embedding PACS databases with HIS/RIS functionality.²⁴³^–²⁴⁶^,²⁴⁶ An update on the ACR-NEMA “Digital Imaging and Communications in Medicine” was given²⁴⁷ and data protection and security issues of PACS were discussed.²⁴⁸ The UCLA Laboratory of H.K. Bernie Huang had a large presence accounting for 20% of the papers presented.²²⁹^–²³¹^,²⁴⁰^,²⁴³^,²⁴⁵

3.4. 1993

Medical Imaging 1993: “PACS Design and Evaluation” was again chaired by R. Gilbert Jost and held in Newport Beach, California. Studies of network bandwidth,²⁴⁹ high-speed networks,²⁵⁰ archives,²⁵¹ and architectures²⁵² were prevalent. Workstation design including a PC workstation,²⁵³ high-resolution 2K diagnostic workstations²⁵⁴ and display functionality²⁵⁵ were presented, along with PACS evaluation at Hammersmith Hospital.²⁵⁶ There were multiple papers covering standardization in Europe,²⁵⁷ ACR-NEMA²⁵⁸^–²⁶⁰ and DICOM v3.0,²⁶¹ including a report of the DICOM demonstration at RSNA’s InfoRAD.²⁶² The importance of interfacing PACS with HIS-RIS was again discussed.²⁶³ Multiple papers showcased emerging technologies in videoconferencing for the purposes of expert radiological consultation,²⁶⁴^,²⁶⁵ teleradiology for the defense medical establishments²⁶⁶ and education.²⁶⁷

3.5. 1994

The third highest number of papers (97) were presented at Medical Imaging 1994: “PACS Design and Evaluation” chaired by RG Jost in Newport Beach, California. Teleradiology systems including for pathology images²⁶⁸^–²⁷⁰ and networking performance including asynchronous transfer mode (ATM) in wide-area networks were reported,²⁶⁸^,²⁷¹^–²⁷³ as was the use of personal computer technology for a radiologic review workstation.²⁷⁴ Again, the importance of interfacing RIS to PACS for enhanced functionality was presented in multiple papers.²⁷⁵^–²⁷⁷ In particular, several papers discussed archiving and the notion of prefetching relevant prior examinations using the RIS-PACS interface.²⁷⁸^–²⁸¹ DICOM conformance was reported in a number of papers²⁸²^–²⁸⁷ as were experiences with modality-specific mini-PACS.²⁸⁸^–²⁹¹ A multi-hospital European PACS,²⁹² Mayo Clinic,²⁹³ UCSF,²⁹⁴ and the US military²⁹⁵ reviewed PACS clinical implementation statuses. Economic assessment of PACS,²⁹⁶ technology assessment,²⁹⁷ image quality,²⁹⁸ and transitioning from film to digital imaging²⁹⁹ were included topics.

3.6. 1995

Medical Imaging 1995 took on a new title “PACS Design and Evaluation: Engineering and Clinical Issues.” R. Gilbert Jost and Samuel J. Dwyer III chaired the conference held for the first time in San Diego, California. Popular topics included DICOM-HL7 interfaces using standards,³⁰⁰^–³⁰⁵ networking technologies³⁰⁶^–³⁰⁹ including ATM, T-1 lines and satellite. Teleradiology examples³¹⁰^–³¹² and radiologists’ technology acceptance³¹³ were shared. Ultrasound³¹⁴ and CT and MR PACS³¹⁵ were described. Experiences with totally digital departments were shared from Europe.³¹⁶^,³¹⁷ Hierarchical storage management design³¹⁸ and fault tolerance for archives³¹⁹ were also topics.

3.7. 1996

Medical Imaging 1996 “PACS Design and Evaluation: Engineering and Clinical Issues” was chaired again by R. Gilbert Jost and Samuel J. Dwyer III. It was held in the familiar location of Newport Beach, California. Long-term archive strategies including use of a 3TB jukebox were topics,³²⁰^,³²¹ as were high-performance servers³²²^,³²³ and high bandwidth networks.³²⁴^,³²⁵ The DICOM standard,³²⁶^–³²⁸ use of the World-Wide-Web³²⁹ and RIS-to-PACS integration³³⁰ were popular paper topics. Specialty PACS including those for endoscopy,³³¹^,³³² digital echocardiography,³³³ mammography,³³⁴ and a telemedicine trial to China³³⁵ were described. Lessons learned from large-scale PACS implementations at UCSF,³³⁶ Mayo Clinic Jacksonville³³⁷ and Japan³³⁸ were shared. Direct digital radiography (DR) integration with PACS³³⁹ was described, cost analysis for film-based versus digital portable chest systems³⁴⁰ was presented, and a clinical comparison of CR versus screen-film for imaging the critically ill neonate³⁴¹ was reported. A study of the impact and utilization of a PACS display in the ICU setting was described³⁴² as well as functional differences between workstations for use by radiologists versus physicians.³⁴³

3.8. 1997

Medical Imaging 1997 “PACS Design and Evaluation: Engineering and Clinical Issues” was chaired by Steven C. Horii and G. James Blaine. It was held again in Newport Beach, California. In spite of the excitement for technology advances and anticipation of the benefits of digital imaging and PACS, multiple papers presented a more critical view noting the pitfalls and shortcomings³⁴⁴^,³⁴⁵ in a session titled “PACS: Why Has It Taken So Long?” One issue was the lack of RIS integration, creating PACS without the intelligence of the traditional film-based workflow.³⁴⁶^–³⁵² A second issue was the lack of availability of digital images to those needing them outside of radiology.³⁵³^,³⁵⁴ Workstation requirements for very large PACS implementations³⁵⁵ and networking bottlenecks³⁵⁶^,³⁵⁷ were also problematic. Eliot Siegel, Bruce Reiner, et al. at the Baltimore VA Medical Center described their experience with PACS,³⁵⁸ and multiple experiences with teleradiology were detailed.³⁵⁹^–³⁶⁴ Archives including tape solutions were covered³⁶⁵^,³⁶⁶ and data security risks were described.³⁶⁷^–³⁶⁹ CR image postprocessing,³⁷⁰ CR in the Emergency Department³⁷¹ and digital chest radiography,³⁷² digital mammography³⁷³ and dental images³⁷⁴ were among the applications of digital X-rays. Cost and productivity analyses³⁷⁵^,³⁷⁶ were presented. Finally, the notion of PACS as an element of the computerized patient record was considered³⁷⁷ foretelling today’s electronic medical records, along with thoughts for “an information revolution in imaging in healthcare.”³⁷⁸

3.9. 1998

In 1998 the Medical Imaging “PACS Design and Evaluation: Engineering and Clinical Issues” conference made the near-permanent move to San Diego, California. It was again chaired by Steven C. Horii and G. James Blaine. Prominent papers this year included topics in PACS infrastructure including networks,³⁷⁹^,³⁸⁰ archives,³⁸¹ security,³⁸² compression,³⁸³ and workstations.³⁸⁴ Teleradiology applications³⁸⁵^–³⁸⁷ and assessment of PACS across networked sites³⁸⁸^–³⁹⁰ were described. Non-radiologist clinician image review patterns were studied.³⁹¹ Implementation of an HL7-DICOM broker for automated patient demographic data entry at the image acquisition modality was described³⁹² and the impact of a speech recognition report generation system was reported.³⁹³ At this time some institutions were beginning to undergo major hardware and software upgrades to systems and one such experience was shared.³⁹⁴

3.10. 1999

G. James Blaine and Steven C. Horii closed out the century chairing the Medical Imaging 1999 “PACS Design and Evaluation: Engineering and Clinical Issues” conference held in San Diego, California. Multiple papers addressed data security,³⁹⁵^,³⁹⁶ standards,³⁹⁷^–³⁹⁹ and PACS quality control⁴⁰⁰ with one paper alerting to the frequency of failure of high resolution monitors used in many thoracic radiology reading rooms.⁴⁰¹ Papers describing network and archival technologies were prominent.⁴⁰²^–⁴⁰⁴ JPEG and wavelet compression,⁴⁰⁵ the use of PACS databases for digital atlases,⁴⁰⁶ and post-processing techniques required for optimal display of CR images⁴⁰⁷^,⁴⁰⁸ were presented. Many sites had not yet adopted digital projection radiography so X-ray film digitizers were often required. Laser versus charge-coupled-device (CCD) digitizers were compared in a paper by Gitlin.⁴⁰⁹ Often placement of digital workstations were not optimal having to work around spaces created for analog film display and workflow. Reiner, Siegel, and Rostenberg presented important work in redesigning the reading room for PACS.⁴¹⁰ Along these lines, Horii, Kundel, et al. pointed out the shift in workflow and the consequences of the lack of automation of steps previously handled by radiology film librarians.⁴¹¹ Figure 2 (top) shows the distribution of the sum of topics presented during the 1990s meetings.

Fig. 2 — Distribution of the sum of topics presented during the 1990s meetings (top), 2000s meetings (middle), and 2010s meetings (bottom). The topics to the right with horizontal line fill are new topics to the decade.

4. 2000s PACS Conferences

4.1. 2000

At the Medical Imaging 2000 “PACS Design and Evaluation: Engineering and Clinical Issues” conference held in San Diego, CA and chaired by G James Blaine and Eliot L. Siegel, several PACS visionaries shared their experiences with PACS development and clinical implementations. These included a history of PACS presented by Samuel J Dwyer III;⁴¹² Heinze Lemke’s look at PACS in Europe;⁴¹³ Guenther Gell’s review of the radiological PACS at the University of Graz, Austria;⁴¹⁴ HK Bernie Huang’s experiences at UCLA and UCSF;⁴¹⁵ Eliot Siegel’s review of PACS adoption at the Department of Veterans Affairs;⁴¹⁶ Anna Chacko’s description of PACS implementation at the Department of Defense;⁴¹⁷ David Channin’s experience with PACS at Northwestern Memorial Hospital;⁴¹⁸ and Hee-Joung Kim’s review of PACS at Yonsei University Colleges of Medicine and Dentistry in Seoul, South Korea.⁴¹⁹ Compression was a big topic as image volume and examination size continued to increase.⁴²⁰^–⁴²⁴ Implementation of DICOM 3.0⁴²⁵ and moving a live PACS with zero downtime⁴²⁶ were presented.

4.2. 2001

For the Medical Imaging 2001 meeting the conference name was changed to “PACS and Integrated Medical Information Systems: Design and Evaluation” to meet the growing realization that PACS without medical information systems was a PACS without knowledge. The meeting was chaired by Eliot L. Siegel and HK Bernie Huang and held in San Diego, California. There continued to be reports of PACS implementations⁴²⁷^–⁴²⁹ including in China.⁴³⁰^,⁴³¹ Digital projection radiography was increasingly being used including CR and DR technologies.⁴³²^,⁴³³ Concerns over image display quality were raised as use of digital projection radiography increased⁴³⁴^,⁴³⁵ and the DICOM committee included an image display consistency test in the standard.⁴³⁶ An additional new DICOM module addressed structured reporting.⁴³⁷ Information security and adhering to HIPAA (Health Insurance Portability and Accountability Act) were discussed.⁴³⁸^–⁴⁴⁰ The Integrating the Healthcare Enterprise (IHE) initiative established in 1998 was now being implemented. One of the profiles addressed the difficult management and presentation of grouped procedures.⁴⁴¹ Assessing imaging examination results outside of radiology,⁴⁴² challenges associated with incorporating non radiological images into the EMR,⁴⁴³ and medical-legal issues were discussed.⁴⁴⁴

4.3. 2002

The Medical Imaging 2002 “PACS and Integrated Medical Information Systems: Design and Evaluation” conference was chaired by Eliot L. Siegel and HK Bernie Huang and held in San Diego, California. A common theme at this year’s meeting was reliability and monitoring of PACS operations⁴⁴⁵^–⁴⁴⁷ including the problem of imaging examination demographic data error entry at acquisition.⁴⁴⁸ Multiple papers reviewed PACS evolution, industry, status, along with a cost assessment of PACS in Korea.⁴⁴⁹^–⁴⁵³ A web-based image archive was described⁴⁵⁴ as was an archive upgrade and clinical migration experience,⁴⁵⁵ now becoming necessary as early PACS installations outgrew their storage volumes and technology obsolesced. Financial and workflow analyses⁴⁵⁶ and the difficulty of automating efficient hanging protocols for radiology workstations⁴⁵⁷ were detailed. Standards including the extension of DICOM to other imaging specialties⁴⁵⁸ and the third year of the IHE RSNA demonstration⁴⁵⁹ were presented. Wireless communication at 100 Mbps was explored.⁴⁶⁰

4.4. 2003

The Medical Imaging 2003 “PACS and Integrated Medical Information Systems: Design and Evaluation” conference was chaired by HK Bernie Huang and Osman M. Ratib. It was held in San Diego, California for the sixth year in a row. The meeting began with a special opening on the IHE initiative in Europe.⁴⁶¹ Monitoring PACS loading and performance,⁴⁶² tele-imaging over the international Internet2,⁴⁶³ security,⁴⁶⁴ and DICOM image viewers⁴⁶⁵ were topics covered. A second special session was held on content-based image retrieval.⁴⁶⁶^–⁴⁶⁸ On the display side, compression was used creatively for processing purposes.⁴⁶⁹^,⁴⁷⁰ A database server that enabled more flexible querying of the PACS archive than prior methods was presented.⁴⁷¹ An interesting clinical functionality providing pathology feedback to the radiologist was achieved via monitoring of HL7 feeds.⁴⁷² This value-add capability was not available in any clinical PACS then and few since this initial mention.

4.5. 2004

For Medical Imaging 2004 the PACS conference title changed again, this time to “PACS and Imaging Informatics.” It was chaired by Osman M. Ratib and H.K. Bernie Huang and held in San Diego, California. In a special opening session covering a new paradigm in digital image interpretation, Katherine P. Andriole presented “Transforming the Radiological Interpretation Process: The SCAR TRIP Initiative.” Described in the paper by K.P. Andriole, R.L. Morin, et al.,⁴⁷³ the TRIP Initiative aimed to foster inter-disciplinary research on technological, environmental, and human factors to better manage and exploit the massive amounts of data being produced in medical imaging. With goals to improve the efficiency of interpretation of large data sets, improve the timeliness and effectiveness of communication, and decrease medical errors, ultimately improving the quality and safety of patient care, a call was made for interdisciplinary research into several broad areas: human perception, image processing and computer-aided detection (CAD), visualization, navigation and usability, databases and integration, and evaluation and validation of methods and performance. Standards were reviewed in several papers⁴⁷⁴^,⁴⁷⁵ along with a discussion of the effect of viewing angle response on DICOM-compliant liquid crystal displays.⁴⁷⁶ Compression strategies,⁴⁷⁷ content-based image retrieval for cell pathology,⁴⁷⁸ a web viewer for cardiac images,⁴⁷⁹ and study of human perception and ergonomics to improve workstation user productivity⁴⁸⁰ were among the other interesting topics.

4.6. 2005

Medical Imaging 2005 “PACS and Imaging Informatics” held in San Diego, California, was chaired by Osman M. Ratib and Steven C Horii. A special opening session covered new trends in PACS including reflections on technology adoption,⁴⁸¹ software strategies,⁴⁸² and navigation of large datasets.⁴⁸³^–⁴⁸⁶ The “Operating Room of the Future” was the topic in a special joint session of SPIE and the Computer Assisted Radiology and Surgery (CARS) meetings with representative papers covering workflow.⁴⁸⁷^,⁴⁸⁸ Observer performance papers addressed image quality and monitor display settings.⁴⁸⁹^,⁴⁹⁰ Image compression methodologies,⁴⁹¹^,⁴⁹² grid-computing for multi-dimensional image rendering,⁴⁹³ thin client architecture for image analysis,⁴⁹⁴ and security algorithms⁴⁹⁵ were among the topics covered.

4.7. 2006

Medical Imaging 2006 “PACS and Imaging Informatics” was again held in San Diego, California, and chaired by Steven C. Horii and Osman M. Ratib. Fewer papers were presented at the PACS meeting than previously, as SPIE Medical Imaging specialty conferences split off into their own parallel tracks. Several papers explored display topics optimizing reading room ambient lighting,⁴⁹⁶ to on-demand rendering of oblique slices through 3D volumes⁴⁹⁷ – something not native to most PACS displays at the time. As imaging examination data continued to grow, the impact on archives was a topic of interest⁴⁹⁸^,⁴⁹⁹ as was compression.⁵⁰⁰ Interventional radiology and surgical workflows were discussed.⁵⁰¹^–⁵⁰³ Standards papers were prominent including approaches for structured reporting,⁵⁰⁴ DICOM-RT for radiation therapy,⁵⁰⁵ and document sharing with the IHE cross-enterprise document sharing profile (XDS).⁵⁰⁶^,⁵⁰⁷ The notion of sharing medical images in a reference database⁵⁰⁸ was proposed perhaps foreshadowing the need we have today for data sharing for developing generalizable machine learning models.

4.8. 2007

Medical Imaging 2007 “PACS and Imaging Informatics” marked the 25^th year of PACS conferences. The meeting was again held in San Diego, California, and chaired by Steven C. Horii and Katherine P. Andriole. Papers on solutions for the digital surgical operating room,⁵⁰⁹ therapy,⁵¹⁰ and DICOM for surgery⁵¹¹ were presented. A grid-based implementation of XDS was presented as part of a metropolitan electronic health record in Shanghai.⁵¹² Papers described digital pathology applications and examined the impact of incorporating whole-slide imaging in PACS archives.⁵¹³ The quality of image displays was discussed including high-resolution⁵¹⁴ and color monitors,⁵¹⁵^,⁵¹⁶ mobile display systems,⁵¹⁷ as well as the impact of ambient lighting on detectability of findings.⁵¹⁸ The variability in automated analysis tools for volumetric measurements⁵¹⁹ was presented, as was a toolkit for integrating independent computer-aided detection (CAD) workstations to the diagnostic workflow⁵²⁰ since most CAD applications at the time were accessible only on stand-alone workstations. A report on the gaps in content-based image retrieval⁵²¹ was given, and several papers addressed the use of the now-digital imaging treasure troves of data in PACS for research purposes.⁵²²^–⁵²⁴ An interesting observer study was performed using 3D surface reconstructed CT facial images to ascertain whether viewers could identify individual patients.⁵²⁵

4.9. 2008

The Medical Imaging 2008 “PACS and Imaging Informatics” meeting chaired by Katherine P. Andriole and Khan M. Siddiqui opened with a moment of silence to mark the passing of Samuel J. Dwyer III, affectionately known as “The Father of PACS” (Fig. 3). Dr. Dwyer chaired the second international PACS meeting and eight subsequent conferences. Among the many tributes, Sam was called “a leading light in the swift growth of the field of medical imaging; a leading force in the development of this new science and technology as the conferences developed and grew; he had an ability to predict important technology trends in medical imaging; one of the first to envision the impact of digital technology on the storage, retrieval, communication, and display of medical images, and one of the most active early explorers of the possibilities; a true pioneer in our field.”⁵²⁶

Fig. 3 — Samuel J. Dwyer III (1932 – 2008) – “The Father of PACS.”

Decision support tools and CAD were topics of interest.⁵²⁷^–⁵²⁹ PACS in other specialties and locations including the intensive care unit,⁵³⁰ and the operating room⁵³¹^–⁵³³ were detailed. Standards including health level 7 (HL7) for text exchange,⁵³⁴ DICOM displays⁵³⁵ and DICOM structured reporting (SR)⁵³⁶ were topics. Multiple studies examined display image quality including improved calibration for viewing angle to adjust for the narrow angle-of-regard limitation of early liquid crystal displays (LCDs),⁵³⁷ grayscale and luminance adjustability,⁵³⁸ and attention to ambient lighting and its impact on detection accuracy.⁵³⁹ HIPAA compliance and signature embedding⁵⁴⁰ was a topic. More papers covered research uses of PACS and the ability to query the RIS and PACS databases.⁵⁴¹ Several papers examined the use of texture and shape analyses.⁵⁴²^,⁵⁴³

4.10. 2009

A new name was used to close out the decade: Medical Imaging 2009 “Advanced PACS-Based Imaging Informatics and Therapeutic Applications.” Chaired by Khan M. Siddiqui and Brent J. Liu, the location also changed to Lake Buena Vista, Florida. In keeping with the name change, multiple papers described specialty clinical applications including for spine surgery,⁵⁴⁴ endoscopy,⁵⁴⁵ multiple sclerosis treatment,⁵⁴⁶ breast cancer,⁵⁴⁷ stroke,⁵⁴⁸ telemedicine,⁵⁴⁹ and regional healthcare.⁵⁵⁰ Research databases⁵⁵¹^,⁵⁵² and CBIR⁵⁵³^,⁵⁵⁴ were also topics of interest. Papers on healthcare interoperability⁵⁵⁵ and digital archives⁵⁵⁶^,⁵⁵⁷ were presented. Tools for moving image processing research to the clinical environment were discussed in a paper from Ronald Summers’ laboratory.⁵⁵⁸ Figure 2 (middle) shows the distribution of the sum of topics presented during the 2000s meetings.

5. 2010s PACS Conferences

5.1. 2010

Medical Imaging 2010 “Advanced PACS-Based Imaging Informatics and Therapeutic Applications” was held in San Diego, California, and chaired by Brent J. Liu and William W. Boonn. Standard topics with a new approach were presented including automated text detection on images for de-identification of pixel data in compliance with HIPAA,⁵⁵⁹ and DICOM structured reporting⁵⁶⁰ and image transmission.⁵⁶¹ Report indexing and search⁵⁶² and semantic annotation of images⁵⁶³ were presented. A zero-footprint 3D visualization system⁵⁶⁴ was described in contrast to the stand-alone advanced post-processing systems of prior years, and an update on TRIP⁵⁶⁵ was given. Development of an automated tracking system for radiology feedback and incidental finding follow-up was presented,⁵⁶⁶ and the first SPIE Medical Imaging meeting mention of the use of a GPU was given in a paper evaluating volumetric segmentation of multiple sclerosis lesions.⁵⁶⁷

5.2. 2011

Medical Imaging 2011 “Advanced PACS-Based Imaging Informatics and Therapeutic Applications” was held in Lake Buena Vista, Florida in the alternating location format and chaired by William W. Boonn and Brent J. Liu. Multiple papers explored radiology reporting including the Breast Imaging-Reporting and Data System (BI-RADS) structured format and follow-up,⁵⁶⁸ DICOM structured reporting (SR) of organ radiation dose,⁵⁶⁹ automated detection of adrenal findings as documented in reports,⁵⁷⁰ database searches for uncovering radiology billing and coding errors,⁵⁷¹ and multimedia electronic patient records.⁵⁷² Use of GPU computing⁵⁷³ and web-based image transmission and display⁵⁷⁴ were again topics of interest. IHE for surgery⁵⁷⁵ was discussed, and comparison of 2D versus 3D mammography acquisition and display devices were examined via an observer study.⁵⁷⁶

5.3. 2012

Medical Imaging 2012 marked thirty years of PACS meetings. It kept the previous year’s title “Advanced PACS-Based Imaging Informatics and Therapeutic Applications” and went back to San Diego, California. The conference was again chaired by William W. Boonn and Brent J. Liu. Cloud-based storage of medical images was mentioned for the first time,⁵⁷⁷ and display of images on a small-footprint iPAD device was discussed.⁵⁷⁸ Report annotation,⁵⁷⁹ image retrieval,⁵⁸⁰ and data mining of DICOM-RT (radiation therapy) objects were presented.⁵⁸¹ The value of digital stores of images and relevant information was being utilized for CAD systems.⁵⁸²^,⁵⁸³

5.4. 2013

Medical Imaging 2013 “Advanced PACS-Based Imaging Informatics and Therapeutic Applications” was back in Lake Buena Vista, Florida. The meeting was chaired by Maria Y. Law and William W. Boonn. Topics covered included CAD,⁵⁸⁴ teleradiology with secure cloud storage,⁵⁸⁵ enhancements to the continually evolving DICOM standard including series transmission,⁵⁸⁶ and integration of PACS and CAD systems.⁵⁸⁷ Open-source research PACS including XNAT,⁵⁸⁸ and MIRC-compliant (Medical Imaging Resource Center) digital radiology teaching files⁵⁸⁹ were presented. Infrastructure for the digital operating room⁵⁹⁰ was discussed.

5.5. 2014

Medical Imaging 2014 changed titles to “PACS and Imaging Informatics: Next Generation and Innovations.” The meeting chaired by Maria Y. Law and Tessa S. Cook was held back in San Diego, CA. An interesting collection of topics presented included a remote volume rendering pipeline,⁵⁹¹ integration of medical images into a mobile device for bedside viewing,⁵⁹² and medical imaging document sharing using the IHE XDS profile.⁵⁹³ Research data collections⁵⁹⁴ and collaborative frameworks for data mining⁵⁹⁵ were presented. Incorporating intelligence into structured radiology reports⁵⁹⁶ was a paper of interest.

5.6. 2015

Medical Imaging 2015 “PACS and Imaging Informatics: Next Generation and Innovations” was chaired by Tessa S. Cook and Jianguo Zhang. It was held in Orlando, Florida. “Big Data” and how to manage and exploit it was presented in multiple papers.⁵⁹⁷^–⁶⁰¹ Future trends and next generation PACS were discussed,⁶⁰²^,⁶⁰³ including pathology PACS.⁶⁰⁴^,⁶⁰⁵ A paper including quantitative imaging features and extending a medical imaging database to oncology⁶⁰⁶ was given. Ingesting outside imaging examinations was also a topic.⁶⁰⁷ Monitoring radiation dose⁶⁰⁸ continued to be of interest.

5.7. 2016

Medical Imaging 2016 “PACS and Imaging Informatics: Next Generation and Innovations” was chaired by Jianguo Zhang and Tessa S. Cook and held in San Diego, CA. Radiomics was the topic of several papers for classification of breast cancer⁶⁰⁹ and lung nodules.⁶¹⁰ 3D printing for cardiac procedure planning was a topic,⁶¹¹ as was smartphone use for clinical trials.⁶¹² Clinical decision support tools were presented⁶¹³^,⁶¹⁴ and high performance computing for medical image processing using Amazon web services was assessed.⁶¹⁵ Deep learning and the combination of human and machine intelligence was explored in multiple papers.⁶¹⁶^–⁶¹⁸

5.8. 2017

Medical Imaging 2017 marked the final name change to date: “Imaging Informatics for Healthcare, Research and Applications.” The meeting was held in Orlando, Florida and chaired by Tessa S. Cook and Jianguo Zhang. Image quantification, classification and analysis using radiomics, and convolutional neural networks (CNN) of machine and deep learning were dominant topics.⁶¹⁹^–⁶²³ 3D printing papers were presented,⁶²⁴^,⁶²⁵ as were clinical decision support applications to reduce radiation dose.⁶²⁶ Mobile devices were described for 3D wound care⁶²⁷ and DICOM was still a topic at the meeting, this time for image quantification secondary capture.⁶²⁸

5.9. 2018

Medical Imaging 2018 “Imaging Informatics for Healthcare, Research and Applications” was held in Houston, Texas, for the first time. It was chaired by Jianguo Zhang and Po-Hao Chen. The meeting opened with a debate between Bradley J. Erickson and Eliot L. Siegel on “Will Computers Replace Radiologists for Primary Reads in 20 Years?,”⁶²⁹ and an introduction of H.K. Bernie Huang’s textbook PACS-Based Multimedia Imaging Informatics 3^rd Edition.⁶³⁰ Papers covered histopathology whole-slide image and genomic data,⁶³¹ crowd-sourced image annotation⁶³² and many presentations on machine learning.⁶³³^–⁶³⁹ 3D printing was also of interest.⁶⁴⁰

5.10. 2019

Medical Imaging 2019 “Imaging Informatics for Healthcare, Research and Applications” was held in San Diego, California, and chaired by Po-Hao Chen and Peter R. Bak. The dominating paper topic was deep learning with multiple applications including classification of thoracic radiographs,⁶⁴¹ breast tumor segmentation,⁶⁴² optic disc segmentation in fundus images,⁶⁴³ molecular subtype prediction in glioblastoma multiforme,⁶⁴⁴ and vertebrae segmentation on CT images.⁶⁴⁵ Newer machine learning architectural approaches were presented including generative adversarial networks (GANs) applied to electronic cleansing on CT colonography⁶⁴⁶ and breast cancer detection,⁶⁴⁷ and a long-short-term memory (LSTM) model was used for sequence labeling in clinical reports.⁶⁴⁸ Papers on 3D printing were also presented.⁶⁴⁹^–⁶⁵¹ Figure 2 (bottom) shows the distribution of the sum of topics presented during the 2010’s meetings as they have evolved from the 1990s and the 2000s.

6. 2020s PACS Conferences

6.1. 2020

Medical Imaging 2020 “Imaging Informatics for Healthcare, Research and Applications” was held in Houston, Texas, and chaired by Po-Hao Chen and Thomas M. Deserno. While papers were included on a new generation of PACS based on artificial intelligence,⁶⁵² cloud platforms for CAD and collaboration,⁶⁵³ and 3D printing,⁶⁵⁴ the overwhelming number of papers presented were on deep learning,⁶⁵⁵^–⁶⁶¹ including some novel architectures: unsupervised learning,⁶⁶² 3D attention U-Net,⁶⁶³ and GANs.⁶⁶⁴

6.2. 2021

Due to the COVID-19 pandemic, Medical Imaging 2021 “Imaging Informatics for Healthcare, Research and Applications” was held virtually online. The conference was chaired by Thomas M. Deserno and Brian J. Park. Understandably, several papers described applications to aid in the management of patients with COVID.⁶⁶⁵^–⁶⁶⁷ Unsupervised⁶⁶⁸ deep learning, LSTM architectures,⁶⁶⁹ and GANs⁶⁷⁰ were again popular paper topics. Challenges with privacy risks in deep learning models were described.⁶⁷¹ Handheld device displays,⁶⁷² 3D printing challenges,⁶⁷³ and integrated PACS workflow⁶⁷⁴ were also presented.

6.3. 2022

Medical Imaging 2022 “Imaging Informatics for Healthcare, Research and Applications” was held back in San Diego, California, and again chaired by Thomas M. Deserno and Brian J. Park. The radiology reading room in the era of COVID-19 was described,⁶⁷⁵ operating room workflow analysis,⁶⁷⁶ and image de-identification using cloud services.⁶⁷⁷ As in recent years, the bulk of papers presented explored topics in machine learning including federating learning approaches,⁶⁷⁸^,⁶⁷⁹ CNNs for respiratory disease management,⁶⁸⁰^,⁶⁸¹ uncertainty quantification in deep learning,⁶⁸² encoder-decoder architectures,⁶⁸³ and clinical implementation of deep learning applications into the radiology workflow.⁶⁸⁴

7. Conclusion

In total, 2,428 papers have been presented through the 40 years of SPIE PACS conferences. The conference has undergone eight name changes. The most frequent meeting locations were San Diego, California, eighteen times; Newport Beach, California, eleven times; and the Orlando area of Florida five times. Several conference chairs/co-chairs served multiple times including Sam Dwyer the most at nine conference chairs, Gil Jost at eight, Steve Horii at six, and H.K. Bernie Huang served five times.

The first PACS conferences covered the concept of image management systems/PACS, its infrastructure and components for image acquisition, network transmission, storage devices, display workstations, and architectures. Image processing, digital projection radiography (CR/DR), and early ACR-NEMA standards were also discussed. Key researchers of the decade were: Andre J. Duerinckx (Philips Ultrasound, Inc), Samuel J Dwyer III (University of Kansas and University of Virginia), R. Gilbert Jost and G. James Blaine (University of Washington, St Louis, Mallincrodt Institute), Steven C. Horii (NYU, Georgetown and University of Pennsylvania), Ronald L. Arenson (University of Pennsylvania and UCSF), and H.K. Bernie Huang (UCLA and UCSF). Many industry researchers presented their work.

In the 1990s many of the same topics were covered with a focus on systems implementations, advances in networks, teleradiology, standards now evolving to DICOM, and display workstations by functionality (radiologist diagnostic versus clinician review). Security and ergonomics and workflow appeared as paper topics of interest. CR/DR advances were covered in the Medical Physics conference. H.K. Bernie Huang’s laboratories at UCLA and subsequently UCSF were major contributors along with R.G. Jost, G.J. Blaine (University of Washington), Janice Honeyman-Buck, Edward V. Staab and M.M. Frost (University of Florida), S.K. Mun (Georgetown), S.C. Horii, R.L. Arenson and S.B. Seshadri (University of Pennsylvania), and S.J. Dwyer III (University of Virginia).

In the 2000s many PACS implementations and lessons learned were described including US military instillations and many international examples. Clinical applications in radiology, radiation therapy, pathology, and surgery were presented along with the research benefits of digital data for content based image retrieval, image processing and analysis, and radiology teaching files. Imaging informatics concepts became fundamentals to medical imaging including standards, security, database management, architectures, display technologies and perception. H.K. Bernie Huang’s (UCSF) and Eliot Siegel’s (University of Maryland) laboratories were main contributors to the SPIE Medical Imaging conferences during this time.

From 2010-2019 major topics included imaging informatics concepts, clinical PACS examples, intelligent databases and data mining, efficient radiology workflow, and clinical applications. New topics appeared including decision support, cloud archives and cloud computing, big data uses and research collaborations, and 3D printing applications. Many machine and deep learning and radiomics papers were presented. Brent J. Liu’s laboratory from the University of Southern California produced many papers on a variety of topics.

So far in the 2020s, machine and deep learning applications continue to be of interest and are covering more nuanced concepts including advanced architectures (GANs, LSTMs), multimodal and unsupervised deep learning, cloud computing, and federated learning. Concerns around data security and patient privacy, bias and uncertainty metrics have also been described. It will be exciting to see what the future SPIE Medical Imaging PACS conferences will bring forward as new technologies, approaches and clinical applications.

Acknowledgments

Thank you to the enthusiastic attendees, speakers, and poster presenters; conference committees and chairs; and SPIE staff over the past forty years who have made the SPIE Medical Imaging: PACS Conference such a success.

Biography

Katherine P. Andriole is an Associate Professor of Radiology at Brigham and Women’s Hospital, Harvard Medical School, where she is Director of Research at the Mass General Brigham Center for Clinical Data Science. She studied biomedical engineering at Duke University and Electrical Engineering and Medicine at Yale University where her PhD research was in classical machine learning. Dr. Andriole completed postdoctoral fellowships at the University of California at Los Angeles and the University of California at San Francisco Departments of Radiology. Her research has involved technical as well as clinically relevant developments in medical imaging informatics, data analytics and machine learning. Dr. Andriole is a passionate educator mentoring more than 90 trainees. She has served in multiple leadership roles for the Society for Imaging Informatics in Medicine (SIIM), the Radiological Society of North America (RSNA), and the American College of Radiology (ACR), and is a past chair of the SPIE Medical Imaging PACS and Imaging Informatics Conference. Dr. Andriole is an elected Senior Member of SPIE, and has been inducted into the College of SIIM Fellows and the Fellowship of the ACR. She has received the RSNA Honored Educator Award multiple times, the SIIM gold medal, and the inaugural RADxx Trailblazer Award recognizing a pioneering woman leader in imaging informatics.

Disclosures

No conflicts of interest are declared by the author.

References

1.Dwyer S. J., III, et al. , “Cost of managing digital diagnostic images for a 614 bed hospital,” Proc. SPIE 0318, 3 (1982). 10.1117/12.967614 [DOI] [PMC free article] [PubMed] [Google Scholar]
2.Dwyer S. J., III, et al. , “Salient characteristics of a distributed diagnostic imaging management system for a radiology department,” Proc. SPIE 0318, 194 (1982). 10.1117/12.967645 [DOI] [Google Scholar]
3.Duerickx A. J., Pisa E. J., “Filmless picture archiving and communication in diagnostic radiology,” Proc. SPIE 0318, 9 (1982). 10.1117/12.967615 [DOI] [Google Scholar]
4.Vizy K. N., “Digital radiography and picture archiving and communication systems (PACS)”. Proc. SPIE 0318, 348 (1982). 10.1117/12.967674 [DOI] [Google Scholar]
5.Staab E. V., et al. , “Medical image communication system: plan, management and initial experience in prototype at the University of North Carolina,” Proc. SPIE 0318, 19 (1982). 10.1117/12.967616 [DOI] [Google Scholar]
6.Bohm M., et al. , “Image management in the system CA/1,” Proc. SPIE 0318, 161 (1982). 10.1117/12.967640 [DOI] [Google Scholar]
7.Cox J. R., et al. , “Study of a distributed picture archiving and communication system for radiology,” Proc. SPIE 0318, 133 (1982). 10.1117/12.967635 [DOI] [Google Scholar]
8.Maguire G. Q., Jr., et al. , “Image processing requirements in hospitals and an integrated systems approach,” Proc. SPIE 0318, 206 (1982). 10.1117/12.967647 [DOI] [Google Scholar]
9.Arenson R. L., et al. , “Comprehensive radiology management system without picture archival and communication system (PACS),” Proc. SPIE 0318, 334 (1982). 10.1117/12.967671 [DOI] [Google Scholar]
10.Arenson R. L., et al. , “Fiber optic communication system for medical images,” Proc. SPIE 0318, 74 (1982). 10.1117/12.967626 [DOI] [Google Scholar]
11.Skinner F. L., et al. , “The teleradiology field demonstration,” Proc. SPIE 0318, 168 (1982). 10.1117/12.967641 [DOI] [Google Scholar]
12.Blom G. M., “Optical disc data storage,” Proc. SPIE 0318, 43 (1982). 10.1117/12.967621 [DOI] [Google Scholar]
13.Billingsley F. C., “Landsat computer-compatible tape family,” Proc. SPIE 0318, 278 (1982). 10.1117/12.967662 [DOI] [Google Scholar]
14.Schneider R. H., “The role of standards in the development of systems for communication and archiving medical images,” Proc. SPIE 0318, 270 (1982). 10.1117/12.967659 [DOI] [Google Scholar]
15.Prewitt J. M. S., “IEEE logical format for external exchange of image data bases,” Proc. SPIE 0318, 272 (1982). 10.1117/12.967660 [DOI] [Google Scholar]
16.Wake R. H., et al. , “Equipment manufacturers’ view on PACS,” Proc. SPIE 0318, 430 (1982). 10.1117/12.967690 [DOI] [Google Scholar]
17.Glenn W., et al. , “The medical community’s view on PACS,” Proc. SPIE 0318, 475 (1982). 10.1117/12.967695 [DOI] [Google Scholar]
18.Huang H. K., et al. , “Dual-potential imaging in digital radiography,” Proc. SPIE 0372, 122 (1982). 10.1117/12.934504 [DOI] [Google Scholar]
19.Templeton A. W., “Keynote address: concepts of a peripheralized image management system,” Proc. SPIE 0418, 2 (1983). 10.1117/12.935950 [DOI] [Google Scholar]
20.Marion J. L., “Analysis of justification for modality integration,” Proc. SPIE 0418, 17 (1983). 10.1117/12.935953 [DOI] [Google Scholar]
21.Duerinckx A. J., “PACS status review: 1983,” Proc. SPIE 0418, 68 (1983). 10.1117/12.935961 [DOI] [Google Scholar]
22.Cywinski J. K., et al. , “Medical image distribution, storage, and retrieval network: the M/NET,” Proc. SPIE 0418, 74 (1983). 10.1117/12.935962 [DOI] [Google Scholar]
23.Blaine G. J., et al. , “PACS workbench at mallinckrodt institute of radiology (MIR),” Proc. SPIE 0418, 80 (1983). 10.1117/12.935963 [DOI] [PMC free article] [PubMed] [Google Scholar]
24.Yoshizaki O., et al. , “Total medical imaging system,” Proc. SPIE 0418, 127 (1983). 10.1117/12.935971 [DOI] [Google Scholar]
25.Rutherford H. G., Gray M. J., “Digital light box, one of the integral pieces of PACS,” Proc. SPIE 0418, 54 (1983). 10.1117/12.935960 [DOI] [Google Scholar]
26.Zeleznik M. P., et al. , “PACS user level requirements,” Proc. SPIE 0418, 172 (1983). 10.1117/12.935978 [DOI] [Google Scholar]
27.Huang H. K., et al. , “Design and implementation of multiple digital viewing stations,” Proc. SPIE 0418, 189 (1983). 10.1117/12.935980 [DOI] [Google Scholar]
28.Flynn M., et al. , “Requirements for the display and analysis of three-dimensional medical image data,” Proc. SPIE 0418, 213 (1983). 10.1117/12.935984 [DOI] [Google Scholar]
29.Anderson W. H., et al. , “Implementation of a diagnostic display and image manipulation node,” Proc. SPIE 0418, 225 (1983). 10.1117/12.935985 [DOI] [Google Scholar]
30.Cahill P. T., et al. , “ICDBM: an image communications and data base management system for radiological imaging,” Proc. SPIE 0418, 134 (1983). 10.1117/12.935972 [DOI] [Google Scholar]
31.Zeleznik M. P., et al. , “PACS data base design,” Proc. SPIE 0418, 287 (1983). 10.1117/12.935995 [DOI] [Google Scholar]
32.Baxter B., et al. , “What types of standards would be useful in PACS activities?” Proc. SPIE 0418, 146 (1983). 10.1117/12.935975 [DOI] [Google Scholar]
33.Maguire G. Q., Jr., et al. , “Message protocols for radiologic consultations over a local area network,” Proc. SPIE 0418, 160 (1983). 10.1117/12.935977 [DOI] [Google Scholar]
34.Gitlin J. N., et al. , “Professional acceptance of electronic images in radiologic practice,” Proc. SPIE 0418, 258 (1983). 10.1117/12.935991 [DOI] [Google Scholar]
35.Arenson R. L., et al. , “Early experience with fiber optic picture archival communication system (PACS),” Proc. SPIE 0418, 116 (1983). 10.1117/12.935969 [DOI] [Google Scholar]
36.Horii S., et al. , “Broadband coaxial cable image viewing and processing for radiology,” Proc. SPIE 0418, 247 (1983). 10.1117/12.935990 [DOI] [Google Scholar]
37.Drexler J., “Drexon optical storage for digital picture archiving applications,” Proc. SPIE 0418, 30 (1983). 10.1117/12.935955 [DOI] [Google Scholar]
38.Wade G. J., “Storing medical images on high density digital tape recorders,” Proc. SPIE 0418, 36 (1983). 10.1117/12.935956 [DOI] [Google Scholar]
39.Russell J. T., DeForest R., “Stationary card optical digital storage system,” Proc. SPIE 0418, 42 (1983). 10.1117/12.935957 [DOI] [Google Scholar]
40.Dunham J. G., et al. , “Compression for picture archiving and communication in radiology,” Proc. SPIE 0418, 201 (1983). 10.1117/12.935982 [DOI] [Google Scholar]
41.Quinn J. F., et al. , “Data compression techniques for CT image archival,” Proc. SPIE 0418, 209 (1983). 10.1117/12.935983 [DOI] [PubMed] [Google Scholar]
42.Huang H. K., et al. , “Digital radiology at the University of California, Los Angeles: a feasibility study,” Proc. SPIE 0418, 259 (1983). 10.1117/12.935992 [DOI] [PMC free article] [PubMed] [Google Scholar]
43.Herron J. M., et al. , “X-ray imaging with two-dimensional charge-coupled device (CCD) Arrays,” Proc. SPIE 0486, 141 (1984). 10.1117/12.943211 [DOI] [Google Scholar]
44.Schwenker R. P., “Film-screen digital radiography,” Proc. SPIE 0486 (1984). 10.1117/12.943212 [DOI] [PubMed] [Google Scholar]
45.MacMahon H., et al. , “The effect of pixel size on the detection rate of early pulmonary sarcoidosis in digital chest radiographic systems,” Proc. SPIE 0486, 14 (1984). 10.1117/12.943193 [DOI] [Google Scholar]
46.Lisk K. G., “SMPTE test pattern for certification of medical diagnostic display devices,” Proc. SPIE 0486, 79 (1984). 10.1117/12.943201 [DOI] [Google Scholar]
47.Lenz R., “Processing and presentation of 3D images,” Proc. SPIE 0515, 298 (1984). 10.1117/12.964776 [DOI] [Google Scholar]
48.Graves W. L., et al. , “Modeling and graphic display system for cardiovascular research using random 3-D data,” Proc. SPIE 0515, 304 (1984). 10.1117/12.964777 [DOI] [Google Scholar]
49.Chen L. S., et al. , “3D83 – an easy-to-use software package for three-dimensional display from computed tomograms,” Proc. SPIE 0515, 309 (1984). 10.1117/12.964778 [DOI] [Google Scholar]
50.Risser T., “Distributed image processing and analysis for PACS,” Proc. SPIE 0515, 61 (1984). 10.1117/12.964730 [DOI] [Google Scholar]
51.Hedge S. S., Prewitt J. M. S., “A layered approach to PACS network architecture,” Proc. SPIE 0515, 442 (1984). 10.1117/12.964803 [DOI] [Google Scholar]
52.Shum C. D., et al. , “Design analysis of a wide-band picture communication system,” Proc. SPIE 0515, 66 (1984). 10.1117/12.964732 [DOI] [Google Scholar]
53.Birkner D. A., “Design considerations for a user oriented PACS,” Proc. SPIE 0515, 89 (1984). 10.1117/12.964734 [DOI] [Google Scholar]
54.Hindel R., et al. , “Conceptual models for interactions with PACS,” Proc. SPIE 0515, 145 (1984). 10.1117/12.964744 [DOI] [Google Scholar]
55.Bergey P., et al. , “A linear systems approach to medical image capture and display,” Proc. SPIE 0515, 4 (1984). 10.1117/12.964716 [DOI] [Google Scholar]
56.Cambier J. L., et al. , “Image acquisition and storage for ophthalmic fluorescein angiography,” Proc. SPIE 0515, 224 (1984). 10.1117/12.964762 [DOI] [Google Scholar]
57.Prewitt J. M. S., et al. , “Name-value pair specification for image data headers and logical standards for image data exchange,” Proc. SPIE 0515, 452 (1984). 10.1117/12.964804 [DOI] [Google Scholar]
58.Gray M. J., Rutherford H., “Functional specifications of a useful digital multimodality image workstation,” Proc. SPIE 0515, 8 (1984). 10.1117/12.964717 [DOI] [Google Scholar]
59.Fisher H. D., et al. , “Psychophysical evaluation of the spatial and contrast resolution necessary for a picture archiving and communication system: works in progress,” Proc. SPIE 0515, 13 (1984). 10.1117/12.964718 [DOI] [Google Scholar]
60.Perry J. R., et al. , “Digital image display console design issues,” Proc. SPIE 0515, 18 (1984). 10.1117/12.964719 [DOI] [Google Scholar]
61.Obayashi I., et al. , “Network analysis of picture archiving and communication system,” Proc. SPIE 0515, 109 (1984). 10.1117/12.964737 [DOI] [Google Scholar]
62.Kato H., Kita K., “Toshiba optical disk stores 15000 CT images,” Proc. SPIE 0515, 138 (1984). 10.1117/12.964742 [DOI] [Google Scholar]
63.Vanden Brink J. A., “The commercial challenges of PACS,” Proc. SPIE 0515, 440 (1984). 10.1117/12.964802 [DOI] [Google Scholar]
64.Okagaki T., et al. , “On-line archiving and enhancement of diagnostic electron microscope images in medicine,” Proc. SPIE 0515, 161 (1984). 10.1117/12.964748 [DOI] [Google Scholar]
65.Beltrame F., et al. , “Three dimensional imaging of cells through digital holographic microscopy,” Proc. SPIE 0515, 232 (1984). 10.1117/12.964763 [DOI] [Google Scholar]
66.Bunke H., et al. , “Artificial intelligence and image understanding methods in a system for the automatic diagnostic evaluation of technetium 99-M gated blood pool studies,” Proc. SPIE 0515, 417 (1984). 10.1117/12.964796 [DOI] [Google Scholar]
67.Wang Y., et al. , “Overview of ACR-NEMA digital imaging and communication standard,” Proc. SPIE 0536, 132 (1985). 10.1117/12.947341 [DOI] [Google Scholar]
68.Lawrence G. R., “ACR/NEMA digital image interface standard (an illustrated protocol overview),” Proc. SPIE 0536, 139 (1985). 10.1117/12.947343 [DOI] [Google Scholar]
69.Dwyer S. J., et al. , “A study of archiving requirements for a Radiology Department,” Proc. SPIE 0536, 190 (1985). 10.1117/12.947356 [DOI] [Google Scholar]
70.Siebert J. E., et al. , “Communication network for metropolitan area interhospital image exchange,” Proc. SPIE 0536, 3 (1985). 10.1117/12.947322 [DOI] [Google Scholar]
71.Lo S. C. B., Huang H. K., “Error-free and irreversible radiographic image compression,” Proc. SPIE 0536, 170 (1985). 10.1117/12.947351 [DOI] [Google Scholar]
72.Moran P. R., “Eigen-representations, data compression and transmission for medical images and related structures,” Proc. SPIE 0536, 183 (1985). 10.1117/12.947355 [DOI] [Google Scholar]
73.Murphy R. E., Lau R., “Very high resolution interactive medical display system,” Proc. SPIE 0536, 57 (1985). 10.1117/12.947330 [DOI] [Google Scholar]
74.Horii S. C., et al. , “Design considerations for image viewstations,” Proc. SPIE 0536, 80 (1985). 10.1117/12.947333 [DOI] [Google Scholar]
75.Maydell U. M., Davis W. A., “Simulation of an interactive workstation for image display,” Proc. SPIE 0536, 110 (1985). 10.1117/12.947337 [DOI] [Google Scholar]
76.Gray M. J., et al. , “Features of a networked medical image workstation called M/Net,” Proc. SPIE 0536, 117 (1985). 10.1117/12.947338 [DOI] [Google Scholar]
77.Massicotte J. B., et al. , “A menu-driven user interface for a physician’s imaging console,” Proc. SPIE 0536, 158 (1985). 10.1117/12.947347 [DOI] [Google Scholar]
78.Janjua A., Racionzer D., “A multimodality image display and image processing system,” Proc. SPIE 0536, 165 (1985). 10.1117/12.947349 [DOI] [Google Scholar]
79.Lehr J. L., “Comparison exam: impact on PACS,” Proc. SPIE 0536, 126 (1985). 10.1117/12.947340 [DOI] [Google Scholar]
80.Benson H. R., et al. , “Integration of radiological reporting systems (RRS) into a picture archiving and communication systems (PACS),” Proc. SPIE 0536, 214 (1985). 10.1117/12.947364 [DOI] [Google Scholar]
81.Fisher J. H., Vittori W., “The clinical workstation: integration of medical images into clinical care,” Proc. SPIE 0536, 148 (1985). 10.1117/12.947344 [DOI] [Google Scholar]
82.Mun S. K., et al. , “Development of PACS at Georgetown University Radiology Department,” Proc. SPIE 0536, 229 (1985). 10.1117/12.947366 [DOI] [Google Scholar]
83.Thompson B. G., et al. , “PACS: part of an integrated communications system,” Proc. SPIE 0536, 237 (1985). 10.1117/12.947368 [DOI] [Google Scholar]
84.Cywinski J. K., et al. , “Cost-benefit implications of automated PACS for digital modalities,” Proc. SPIE 0536, 15 (1985). 10.1117/12.947324 [DOI] [Google Scholar]
85.Johnston R. E., et al. , “Perceptual standardization,” Proc. SPIE 0536, 44 (1985). 10.1117/12.947328 [DOI] [Google Scholar]
86.Shalev S., et al. , “Pseudo-3D imaging with the DICOM-8,” Proc. SPIE 0555, 63 (1985). 10.1117/12.949477 [DOI] [Google Scholar]
87.Mun S. K., et al. , “Design and implementation of PACS at Georgetown University Hospital,” Proc. SPIE 0555, 217 (1985). 10.1117/12.949497 [DOI] [Google Scholar]
88.Stockbridge C., Ravin C. E., “Phased implementation of AT&T PACS at Duke University Medical Center,” Proc. SPIE 0671, 169 (1986). 10.1117/12.966692 [DOI] [Google Scholar]
89.Lubinsky A. R., et al. , “Storage phosphor system for computed radiography: optical effects and detective quantum efficiency (DQE),” Proc. SPIE 0767, 167 (1987). 10.1117/12.966995 [DOI] [Google Scholar]
90.Yorker J. G., “Photostimulated luminescence digital radiography system characterization II: Image quality measurements,” Proc. SPIE 0767, 162 (1987). 10.1117/12.966994 [DOI] [Google Scholar]
91.Blume H., Kamiya K., “Auto-ranging and normalization versus histogram modifications for automatic image processing of digital radiographs,” Proc. SPIE 0767, 371 (1987). 10.1117/12.967021 [DOI] [Google Scholar]
92.Nelson R. S., et al. , “Digital slot scan mammography using CCDs,” Proc. SPIE 0767, 102 (1987). 10.1117/12.966986 [DOI] [Google Scholar]
93.Stewart B. K., Huang H. K., “Dual energy radiography using a single exposure technique,” Proc. SPIE 0767, 154 (1987). 10.1117/12.966993 [DOI] [Google Scholar]
94.Horii S. C., et al. , “The ACR-NEMA exchange medial standards: progress and future directions,” Proc. SPIE 0767, 272 (1987). 10.1117/12.967006 [DOI] [Google Scholar]
95.Ho B. K. T., et al. , “Expandable image compression system: a modular approach,” Proc. SPIE 0767, 286 (1987). 10.1117/12.967008 [DOI] [Google Scholar]
96.van Aken I. W., et al. , “Compressed medical images and enhanced fault detection with an ACR-NEMA compatible picture archiving and communications system,” Proc. SPIE 0767, 290 (1987). 10.1117/12.967009 [DOI] [Google Scholar]
97.Giger M. L., et al. , “Computerized detection of lung nodules in digital chest radiographs,” Proc. SPIE 0767, 384 (1987). 10.1117/12.967022 [DOI] [Google Scholar]
98.Pond G. D., et al. , “Comparison of conventional film/screen to photo-stimulable imaging plate radiographs for intraoperative arteriography and cholangiography,” Proc. SPIE 0914, 139 (1988). 10.1117/12.968625 [DOI] [Google Scholar]
99.Tecotzky M., Andrews-Eurglunes C., “Storage phosphors for medical imaging I: quality assurance considerations and variations in quality,” Proc. SPIE 0914, 143 (1988). 10.1117/12.968626 [DOI] [Google Scholar]
100.Yaffe M., et al. , “Development of a digital mammography system,” Proc. SPIE 0914, 182 (1988). 10.1117/12.968631 [DOI] [Google Scholar]
101.Shaber G. S., Lockard C., Boone H. M., “High resolution digital radiography utilizing CCD planar array,” Proc. SPIE 0914, 262 (1988). 10.1117/12.968640 [DOI] [Google Scholar]
102.Yamasaki K., et al. , “Diagnostic capability of digital chest images,” Proc. SPIE 0914, 577 (1988). 10.1117/12.968683 [DOI] [Google Scholar]
103.Shaber G. S., et al. , “ROC detectability evaluation of a filmless digital radiographic system,” Proc. SPIE 0914, 560 (1988). 10.1117/12.968681 [DOI] [Google Scholar]
104.Ho B. K. T., et al. , “High speed image compression system, prototype and final configuration,” Proc. SPIE 0914, 786 (1988). 10.1117/12.968714 [DOI] [Google Scholar]
105.Blume H., et al. , “The ACR-NEMA digital interface communications standard to compression techniques: status report,” Proc. SPIE 0914, 823 (1988). 10.1117/12.968718 [DOI] [Google Scholar]
106.Lo S. C. B., Mun S. K., “Data compression for a radiology image display system with visual directory,” Proc. SPIE 0914, 1203 (1988). 10.1117/12.968767 [DOI] [Google Scholar]
107.McNeill K. M., et al. , “Comparison of digital workstations and conventional reading for evaluation of user interfaces in digital radiology,” Proc. SPIE 0914, 872 (1988). 10.1117/12.968724 [DOI] [Google Scholar]
108.Fahy J. B., Kim Y., “A consistent DIN/PACS workstation interface based on the MUVIP virtual image processing architecture,” Proc. SPIE 0914, 911 (1988). 10.1117/12.968729 [DOI] [Google Scholar]
109.Horii S. C., et al. , “An eclectic look at viewing station design,” Proc. SPIE 0914 (1988). 10.1117/12.968730 [DOI] [Google Scholar]
110.McNeill K. M., et al. , “Comparison of a digital workstation and a film alternator,” Proc. SPIE 0914, 929 (1988). 10.1117/12.968731 [DOI] [Google Scholar]
111.Beard D., et al. , “Experiment comparing film and the filmplane radiology workstation,” Proc. SPIE 0914, 933 (1988). 10.1117/12.968732 [DOI] [Google Scholar]
112.O’Malley K. G., Giunta J. A., “The alternator: determination of its fundamental features as a basis for design of a PACS diagnostic workstation,” Proc. SPIE 0914, 988 (1988). 10.1117/12.968739 [DOI] [Google Scholar]
113.Kishore S., Seshadri S. B., Arenson R. L., “A MIMS view-station for orthopedic images,” Proc. SPIE 0914, 1023 (1988). 10.1117/12.968743 [DOI] [Google Scholar]
114.Cox J. R., et al. , “An inexpensive electronic viewbox,” Proc. SPIE 0914, 1218 (1988). 10.1117/12.968769 [DOI] [Google Scholar]
115.Kim Y., et al. , “Development of a PC-based radiologic imaging workstation,” Proc. SPIE 0914, 1257 (1988). 10.1117/12.968774 [DOI] [Google Scholar]
116.Humphrey L. M., Ravin C. E., “Film traffic queuing model for the DUMC Radiology Department,” Proc. SPIE 0914, 947 (1988). 10.1117/12.968734 [DOI] [Google Scholar]
117.Blaine G. J., et al. , “Image transmission studies,” Proc. SPIE 0914, 953 (1988). 10.1117/12.968735 [DOI] [Google Scholar]
118.Seshadri S. B., et al. , “Satellite transmission of medical images,” Proc. SPIE 0914, 1416 (1988). 10.1117/12.968799 [DOI] [Google Scholar]
119.List J. S., O’Malley K. G., “The impact of PACS technology on diagnostic cycle time,” Proc. SPIE 0914, 961 (1988). 10.1117/12.968736 [DOI] [Google Scholar]
120.Mun S. K., et al. , “Baseline study of radiology services for the purpose of PACS evaluation,” Proc. SPIE 0914, 978 (1988). 10.1117/12.968738 [DOI] [Google Scholar]
121.ter Haar Romeny B. M., et al. , “Procedures to study the impact of PACS on the logistics within a Diagnostic Imaging Department,” Proc. SPIE 0914, 1159 (1988). 10.1117/12.968760 [DOI] [Google Scholar]
122.Benson H. R., et al. , “Cost analysis for the development of digital imaging network,” Proc. SPIE 0914, 1008 (1988). 10.1117/12.968742 [DOI] [Google Scholar]
123.Bakker A. R., et al. , “PACS costs: modeling and simulation,” Proc. SPIE 0914, 1147 (1988). 10.1117/12.968758 [DOI] [Google Scholar]
124.Kangarloo H., et al. , “Clinical experience with a PACS module in pediatric radiology: clinical viewpoint,” Proc. SPIE 0914, 1036 (1988). 10.1117/12.968744 [DOI] [Google Scholar]
125.Taira R. K., Mankovich N. J., Huang H. K., “One-year experience with a PACS module in pediatric radiology: system viewpoint,” Proc. SPIE 0914, 1046 (1988). 10.1117/12.968745 [DOI] [Google Scholar]
126.Cho P. S., Huang H. K., Tillisch J., “Clinical experience with a digital remote viewing system in coronary care unit,” Proc. SPIE 0914, 1057 (1988). 10.1117/12.968746 [DOI] [Google Scholar]
127.Greberman M., et al. , “The collaborative digital imaging network project,” Proc. SPIE 0914, 1326 (1988). 10.1117/12.968784 [DOI] [Google Scholar]
128.Cerva J., et al. , “Integration of digital imaging network technology into the US Army’s Fixed Facility and Deployable Medical Centers,” Proc. SPIE 0914, 1328 (1988). 10.1117/12.968785 [DOI] [Google Scholar]
129.Mun S. K., et al. , “Development and operational evaluation of PACS network at Georgetown University,” Proc. SPIE 0914, 1334 (1988). 10.1117/12.968786 [DOI] [Google Scholar]
130.Haynor D. R., Rowberg A. H., Loop J. W., “Clinical evaluation of a prototype digital imaging network,” Proc. SPIE 0914, 1341 (1988). 10.1117/12.968787 [DOI] [Google Scholar]
131.Creasy J. L., et al. , “Overview of University of North Carolina at Chapel Hill PACS program,” Proc. SPIE 0914, 1349 (1988). 10.1117/12.968789 [DOI] [Google Scholar]
132.Minato K., Komori M., Nakano Y., “Experience with a small scale all digital CT and MRI clinical service unit: present status of Kyoto University Hospital Image Database and Communication System,” Proc. SPIE 0914, 1356 (1988). 10.1117/12.968790 [DOI] [Google Scholar]
133.Nosil J., et al. , “A prototype multi-modality picture archive and communication system at Victoria General Hospital,” Proc. SPIE 0914, 1362 (1988). 10.1117/12.968791 [DOI] [Google Scholar]
134.Ratib O. M., et al. , “Integration of an MR image network into a clinical PACS,” Proc. SPIE 0914, 1379 (1988). 10.1117/12.968793 [DOI] [Google Scholar]
135.Suzuki M., et al. , “Clinical evaluation of TDF-500 system,” Proc. SPIE 0914, 1398 (1988). 10.1117/12.968796 [DOI] [Google Scholar]
136.Butler D. M., Hamilton C. L., “A prototype relational implementation of the ‘NEMA schema’,” Proc. SPIE 0914, 1066 (1988). 10.1117/12.968747 [DOI] [Google Scholar]
137.Ringleben C. L., et al. , “An ACR-NEMA implementation and PACS architectural implication,” Proc. SPIE 0914, 1069 (1988). 10.1117/12.968748 [DOI] [Google Scholar]
138.Good W. F., et al. , “ACR-NEMA standard: the reality versus the ideal,” Proc. SPIE 0914, 1081 (1988). 10.1117/12.968749 [DOI] [Google Scholar]
139.Awang Y., et al. , “Update of the ACR-NEMA standard committee,” Proc. SPIE 0914, 1406 (1988). 10.1117/12.968797 [DOI] [Google Scholar]
140.Seshadri S. B., et al. , “An image archive with the ACR-NEMA message formats,” Proc. SPIE 0914, 1409 (1988). 10.1117/12.968798 [DOI] [Google Scholar]
141.Kerlin B. D., “The optical memory card as a transportable image archiving medium in a digital imaging network,” Proc. SPIE 0914, 1088 (1988). 10.1117/12.968750 [DOI] [Google Scholar]
142.Fisher P. D., et al. , “Clinically-based archive model for a picture archive and communication system,” Proc. SPIE 0914, 1097 (1988). 10.1117/12.968751 [DOI] [Google Scholar]
143.Mankovich N. J., et al. , “Procedures, films and images in a pediatric radiology image archive: one year’s experience and projections,” Proc. SPIE 0914, 1106 (1988). 10.1117/12.968752 [DOI] [Google Scholar]
144.Martinez R., Nemat M., “Image data base archive design using parallel architectures and expert systems,” Proc. SPIE 0914, 1114 (1988). 10.1117/12.968753 [DOI] [Google Scholar]
145.Kamm K. F., et al. , “Digital image archiving and handling – status and trends,” Proc. SPIE 0914, 1171 (1988). 10.1117/12.968762 [DOI] [Google Scholar]
146.Cohen J., et al. , “A laser disk-based archive, review and communications system for magnetic resonance imaging,” Proc. SPIE 0914, 1344 (1988). 10.1117/12.968788 [DOI] [Google Scholar]
147.Lodder H., et al. , “HIS-PACS coupling: first experiences,” Proc. SPIE 0914, 1141 (1988). 10.1117/12.968757 [DOI] [Google Scholar]
148.Paisner M. W., “Radiology operations systems,” Proc. SPIE 0914, 1391 (1988). 10.1117/12.968795 [DOI] [Google Scholar]
149.Barneveld Binkhuysen F. H., et al. , “First results of the diagnostic evaluation studies and the clinical efficacy evaluation in the Dutch PACS project,” Proc. SPIE 1093, 13 (1989). 10.1117/12.953312 [DOI] [Google Scholar]
150.Minato K., et al. , “PACS development at Kyoto University Hospital: toward integrating digital imaging modalities,” Proc. SPIE 1093, 20 (1989). 10.1117/12.953313 [DOI] [Google Scholar]
151.Lou S. L., et al. , “A CT/MR/US picture archiving and communication system,” Proc. SPIE 1093, 31 (1989). 10.1117/12.953315 [DOI] [Google Scholar]
152.Arenson R. L., et al. , “PACS at Penn,” Proc. SPIE 1093, 50 (1989). 10.1117/12.953317 [DOI] [Google Scholar]
153.Mun S. K., et al. , “Total digital department: implementation strategy,” Proc. SPIE 1093, 133 (1989). 10.1117/12.953326 [DOI] [Google Scholar]
154.Cho P. S., Huang H. K., Tillisch J., “Centralized versus distributed PACS for intensive care units,” Proc. SPIE 1093, 387 (1989). 10.1117/12.953352 [DOI] [Google Scholar]
155.Taira R. K., et al. , “Performance evaluation of a clinical PACS module,” Proc. SPIE 1093, 406 (1989). 10.1117/12.953355 [DOI] [Google Scholar]
156.Jost R. G., et al. , “PACS – is there light at the end of the tunnel?” Proc. SPIE 1093, 74 (1989). 10.1117/12.953319 [DOI] [Google Scholar]
157.Seeley G. W., et al. , “Evaluation of the DuPont teleradiology system,” Proc. SPIE 1093, 106 (1989). 10.1117/12.953322 [DOI] [Google Scholar]
158.Horii S. C., et al. , “A complete image management and communications network for the neuroradiology service at Georgetown University Hospital,” Proc. SPIE 1093, 154 (1989). 10.1117/12.953328 [DOI] [Google Scholar]
159.Saarienen A. O., Goodsitt M. M., Loop J. W., “The logistics of installing PACS in an Existing Medical Center,” Proc. SPIE 1093, 159 (1989). 10.1117/12.953329 [DOI] [Google Scholar]
160.Mun S. K., et al. , “Experience with image management networks at three universities: is the cup half-empty or half-full?” Proc. SPIE 1093, 194 (1989). 10.1117/12.953332 [DOI] [PMC free article] [PubMed] [Google Scholar]
161.ter Haar Romeny B. M., et al. , “PACS efficiency: a detailed quantitative study of the distribution process of films in a clinical environment in the Utrecht University Hospital,” Proc. SPIE 1093, 259 (1989). 10.1117/12.953339 [DOI] [Google Scholar]
162.Goeringer F., Mun S. K., Kerlin B. D., “Digital medical imaging: implementation strategy for the defense medical establishment,” Proc. SPIE 1093, 429 (1989). 10.1117/12.953358 [DOI] [Google Scholar]
163.Siedband M., et al. , “Filmless radiographic system for Army Field Hospitals,” Proc. SPIE 1093, 466 (1989). 10.1117/12.953362 [DOI] [Google Scholar]
164.Nadel L. D., et al. , “Prototype system for digital image management in Combat casualty care,” Proc. SPIE 1093, 511 (1989). 10.1117/12.953367 [DOI] [Google Scholar]
165.Andriessen J. H. T. H., et al. , “Methodology of PACS effectiveness evaluation as part of a technology assessment: the Dutch PACS project extrapolated,” Proc. SPIE 1093, 585 (1989). 10.1117/12.953377 [DOI] [Google Scholar]
166.Mankovich N. J., Taira R. K., “Image archiving hardware and database technology,” Proc. SPIE 1093, 244 (1989). 10.1117/12.953337 [DOI] [Google Scholar]
167.Britt M. O., et al. , “Optical archive organization and strategies for the 1990s,” Proc. SPIE 1093, 498 (1989). 10.1117/12.953365 [DOI] [Google Scholar]
168.Hedgcock M. W., Levitt T. S., Smith S., “Calculating storage needs for an optical archive,” Proc. SPIE 1093, 551 (1989). 10.1117/12.953372 [DOI] [Google Scholar]
169.Martinez R., Nematbakhsh M., “Design and performance evaluation of a high speed fiber optic integrated computer network for a picture archiving and communications system,” Proc. SPIE 1093, 37 (1989). 10.1117/12.953316 [DOI] [Google Scholar]
170.Dallas W. J., et al. , “A fiber-optic network system for PACS,” Proc. SPIE 1093, 85 (1989). 10.1117/12.953320 [DOI] [Google Scholar]
171.Reijns G. L., et al. , “Performance aspects of a PACS using a hardware implemented ACR-NEMA interface for medical image exchange,” Proc. SPIE 1093, 171 (1989). 10.1117/12.953330 [DOI] [Google Scholar]
172.Gee J. C., et al. , “User interface design for a radiological imaging workstation,” Proc. SPIE 1093, 122 (1989). 10.1117/12.953325 [DOI] [Google Scholar]
173.Belanger G., et al. , “Evaluation of a workstation by clinicians,” Proc. SPIE 1093, 214 (1989). 10.1117/12.953334 [DOI] [Google Scholar]
174.Braudes R. E., et al. , “Workstation modelling and development: clinical definition of a picture archiving and communications system (PACS) user interface,” Proc. SPIE 1093, 376 (1989). 10.1117/12.953351 [DOI] [Google Scholar]
175.Dullien R., “Progress in PACS – definition of the principal workstation types,” Proc. SPIE 1093, 438 (1989). 10.1117/12.953359 [DOI] [Google Scholar]
176.Levine B., et al. , “Integration of a RIS with an IMACS,” Proc. SPIE 1093, 183 (1989). 10.1117/12.953331 [DOI] [Google Scholar]
177.Lodder H., et al. , “HIS-PACS coupling in practice,” Proc. SPIE 1093, 301 (1989). 10.1117/12.953343 [DOI] [Google Scholar]
178.Boehme J. M., Choplin T. H., Maynard C. D., “Early experience in interfacing PACS to RIS,” Proc. SPIE 1093, 589 (1989). 10.1117/12.953378 [DOI] [Google Scholar]
179.Saarinen A. O., et al. , “Modeling the economics of PACS: what is important?” Proc. SPIE 1093, 62 (1989). 10.1117/12.953318 [DOI] [Google Scholar]
180.Benson H., et al. , “CAMDIN a cost analysis model for digital imaging networks,” Proc. SPIE 1093, 448 (1989). 10.1117/12.953360 [DOI] [Google Scholar]
181.Parrish D. M., et al. , “Operational modeling for PACS: how do we decide if it’s cost effective?” Proc. SPIE 1093, 457 (1989). 10.1117/12.953361 [DOI] [Google Scholar]
182.Cywinski J. K., Vanden Brink J. A., “Review of experience with PACS cost analysis model,” Proc. SPIE 1093, 535 (1989). 10.1117/12.953369 [DOI] [Google Scholar]
183.Bakker A. R., et al. , “Cost modelling of PACS,” Proc. SPIE 1093, 545 (1989). 10.1117/12.953371 [DOI] [Google Scholar]
184.Andriessen J. H. T. H., et al. , “Savings and costs of a picture archiving and communication system in the University Hospital Utrecht,” Proc. SPIE 1093, 578 (1989). 10.1117/12.953376 [DOI] [Google Scholar]
185.Beard D. V., et al. , “Cost analysis of film image management and four PACS systems,” Proc. SPIE 1234, 10 (1990). 10.1117/12.18938 [DOI] [PubMed] [Google Scholar]
186.Saarienen A. O., et al. , “Potential time savings to radiology department personnel in a PACS-based environment,” Proc. SPIE 1234, 823 (1990). 10.1117/12.19010 [DOI] [Google Scholar]
187.Kundel H. L., Seshadri S. B., Arenson R. L., “Clinical evaluation of PACS: modeling diagnostic value,” Proc. SPIE 1234, 214 (1990). 10.1117/12.19030 [DOI] [Google Scholar]
188.Haynor D. R., et al. , “Clinical evaluation of PACS workstations: methodology and results,” Proc. SPIE 1234, 408 (1990). 10.1117/12.19044 [DOI] [Google Scholar]
189.Razavi M., et al. , “Display conditions and lesion detectability: effect of background light,” Proc. SPIE 1234, 776 (1990). 10.1117/12.19004 [DOI] [Google Scholar]
190.Hedgcock M. W., et al. , “Image degradation in PACS,” Proc. SPIE 1234, 933 (1990). 10.1117/12.19027 [DOI] [Google Scholar]
191.Taira R. K., et al. , “High-resolution workstations for primary and secondary radiology readings,” Proc. SPIE 1234, 18 (1990). 10.1117/12.18939 [DOI] [Google Scholar]
192.Good W. F., et al. , “Implementation of a high-resolution workstation for primary diagnosis of projection radiography images,” Proc. SPIE 1234, 105 (1990). 10.1117/12.18950 [DOI] [Google Scholar]
193.Dwyer S. J., III, et al. , “Experience with high-resolution digital gray-scale display systems,” Proc. SPIE 1234, 132 (1990). 10.1117/12.18966 [DOI] [Google Scholar]
194.Hall C. L., Perry J. H., “Siemens experience in PACS,” Proc. SPIE 1234, 354 (1990). 10.1117/12.19060 [DOI] [Google Scholar]
195.Morin R. L., et al. , “New AS/400-based PACS for MRI and CT,” Proc. SPIE 1234, 326 (1990). 10.1117/12.19041 [DOI] [Google Scholar]
196.Weinberg W. S., et al. , “Development and implementation of ultrasound picture archiving and communication system,” Proc. SPIE 1234, 44 (1990). 10.1117/12.18942 [DOI] [Google Scholar]
197.Horii S. C., et al. , “Validating simulation: comparison of a PACS network model of ultrasound image acquisition with actual performance,” Proc. SPIE 1234, 205 (1990). 10.1117/12.19024 [DOI] [Google Scholar]
198.Blaine G. J., et al. , “ISDN: early experiments as a wide-area extension to LAN-based PACS,” Proc. SPIE 1234, 140 (1990). 10.1117/12.18973 [DOI] [Google Scholar]
199.Prior F. W., et al. , “Impact of node architecture on network performance,” Proc. SPIE 1234, 334 (1990). 10.1117/12.19042 [DOI] [Google Scholar]
200.Wong A. W. K., et al. , “Performance comparisons of image communication networks,” Proc. SPIE 1234, 461 (1990). 10.1117/12.19051 [DOI] [Google Scholar]
201.DeJarnette W. T., “Two chip ACR-NEMA datalink/physical layer implementation,” Proc. SPIE 1234, 541 (1990). 10.1117/12.18967 [DOI] [Google Scholar]
202.Kofakis P. G., et al. , “Image archiving by content: an object-oriented approach,” Proc. SPIE 1234, 275 (1990). 10.1117/12.19037 [DOI] [Google Scholar]
203.Seshadri S. B., et al. , “Software considerations in the design of an image archive,” Proc. SPIE 1234, 2 (1990). 10.1117/12.19052 [DOI] [Google Scholar]
204.D’Lugin J. J., et al. , “Optimization of image transfer from the central archive to workstations in a PACS,” Proc. SPIE 1234, 398 (1990). 10.1117/12.19059 [DOI] [Google Scholar]
205.Seshadri S. B., et al. , “Architecture of an optical jukebox image archive,” Proc. SPIE 1234, 925 (1990). 10.1117/12.19025 [DOI] [Google Scholar]
206.Cooperstein L. A., et al. , “Incorporation of a clinical history into the interpretation process in a PACS environment,” Proc. SPIE 1234, 98 (1990). 10.1117/12.18949 [DOI] [Google Scholar]
207.Levin K., Fielding R., “Methods to prefetch comparison images in image management and communication system,” Proc. SPIE 1234, 270 (1990). 10.1117/12.19036 [DOI] [Google Scholar]
208.Levine B. A., et al. , “Assessment of the integration of a HIS/RIS With a PACS,” Proc. SPIE 1234, 391 (1990). 10.1117/12.19057 [DOI] [Google Scholar]
209.Lee W., et al. , “Integrating a radiology information system with a picture archiving and communications system,” Proc. SPIE 1234, 661 (1990). 10.1117/12.18987 [DOI] [Google Scholar]
210.Jost R. G., et al. , “High-resolution teleradiology applications within the hospital,” Proc. SPIE 1446, 2 (1991). 10.1117/12.27713 [DOI] [Google Scholar]
211.Staab E. V., et al. , “Teleradiology in the local environment,” Proc. SPIE 1446, 16 (1991). 10.1117/12.45257 [DOI] [Google Scholar]
212.Morin R. L., et al. , “Present status and future directions of the Mayo/IBM PACS project,” Proc. SPIE 1446, 436 (1991). 10.1117/12.45302 [DOI] [Google Scholar]
213.Ratib O. M., et al. , “Hospital-integrated PACS at the University Hospital of Geneva,” Proc. SPIE 1446, 330 (1991). 10.1117/12.45289 [DOI] [Google Scholar]
214.Kouwenberg J. M. L., Ottes F. P., Bakker A. R., “European activities towards a hospital-integrated PACS based on open systems,” Proc. SPIE 1446, 357 (1991). 10.1117/12.45292 [DOI] [Google Scholar]
215.Razavi M., et al. , “Clinical evaluation of a 2K x 2K workstation for primary diagnosis in pediatric radiology,” Proc. SPIE 1446, 24 (1991). 10.1117/12.27720 [DOI] [Google Scholar]
216.Beard D. V., et al. , “Radiology workstation for mammography: preliminary observations, eyetracker studies and design,” Proc. SPIE 1446, 289 (1991). 10.1117/12.45284 [DOI] [Google Scholar]
217.Wong A. W. K., et al. , “Multiple communication networks for a radiological PACS,” Proc. SPIE 1446, 73 (1991). 10.1117/12.45262 [DOI] [Google Scholar]
218.Chimiak W. J., Williams R. C., “Using the ACR/NEMA standard with TCP/IP and ethernet,” Proc. SPIE 1446, 93 (1991). 10.1117/12.45263 [DOI] [Google Scholar]
219.Stewart B. K., et al. , “Performance characteristics of an ultra-fast network for PACS,” Proc. SPIE 1446, 141 (1991). 10.1117/12.45267 [DOI] [Google Scholar]
220.Taira R. K., et al. , “Reliability issues in PACS,” Proc. SPIE 1446, 451 (1991). 10.1117/12.45304 [DOI] [Google Scholar]
221.Horii S. C., et al. , “PACS reading time comparison: the workstation versus alternator for ultrasound,” Proc. SPIE 1446, 475 (1991). 10.1117/12.45310 [DOI] [Google Scholar]
222.Umeda T., et al. , “Multi-media PACS integrated with HIS/RIS employing magneto-optical disks,” Proc. SPIE 1446, 199 (1991). 10.1117/12.45273 [DOI] [Google Scholar]
223.Feingold E. R., Seshadri S. B., Arenson R. L., “Folder management on a multimodality PACS display station,” Proc. SPIE 1446, 211 (1991). 10.1117/12.45274 [DOI] [Google Scholar]
224.Lodder H., et al. , “Prefetching: PACS image management optimization using HIS/RIS information,” Proc. SPIE 1446, 227 (1991). 10.1117/12.45276 [DOI] [Google Scholar]
225.Dayhoff R. E., et al. , “Experiences with a comprehensive hospital information system that incorporates image management capabilities,” Proc. SPIE 1446, 323 (1991). 10.1117/12.45288 [DOI] [Google Scholar]
226.King J. L., et al. , “Radiologists’ confidence in detecting abnormalities on chest images and their subjective judgements of image quality,” Proc. SPIE 1446, 268 (1991). 10.1117/12.45281 [DOI] [Google Scholar]
227.van Gennip E. M. S. J., et al. , “Comparison of worldwide opinions on the costs and benefits of PACS,” Proc. SPIE 1446, 442 (1991). 10.1117/12.45303 [DOI] [Google Scholar]
228.Rundle D. A., et al. , “DRILL: a standardized radiology-teaching knowledge base,” Proc. SPIE 1446, 405 (1991). 10.1117/12.45297 [DOI] [Google Scholar]
229.Wong A. W. K., et al. , “On-line performance characteristics of a radiology PACS,” Proc. SPIE 1654, 14 (1992). 10.1117/12.60255 [DOI] [Google Scholar]
230.Eldredge S. L., et al. , “Operation of a clinical PACS,” Proc. SPIE 1654, 349 (1992). 10.1117/12.60287 [DOI] [Google Scholar]
231.Lou S. A., Huang H. K., “Clinical assessment of a neuroradiology PACS,” Proc. SPIE 1654, 373 (1992). 10.1117/12.60289 [DOI] [Google Scholar]
232.Honeyman-Buck J. C., et al. , “PACS in clinical neuroradiology, nuclear medicine and teleradiology,” Proc. SPIE 1654, 383 (1992). 10.1117/12.60290 [DOI] [Google Scholar]
233.Fritz S. L., DeJarnette W. T., “Design of a multivendor PACS network for a university hospital environment,” Proc. SPIE 1654, 559 (1992). 10.1117/12.60313 [DOI] [Google Scholar]
234.Bryan S., et al. , “Evaluation of a hospital-wide PACS: costs and benefits of the Hammersmith PACS instillation,” Proc. SPIE 1654, 573 (1992). 10.1117/12.60317 [DOI] [Google Scholar]
235.Smith D. V., et al. , “Design strategy and implementation of the medical diagnostic image support system at two large military medical centers,” Proc. SPIE 1654, 148 (1992). 10.1117/12.60318 [DOI] [Google Scholar]
236.Behlen F. M., et al. , “User interface optimization in a radiography display console,” Proc. SPIE 1654, 432 (1992). 10.1117/12.60297 [DOI] [Google Scholar]
237.Horii S. C., et al. , “Comparison of case retrieval times: film versus PACS,” Proc. SPIE 1654, 236 (1992). 10.1117/12.60275 [DOI] [PubMed] [Google Scholar]
238.Dwyer S. J., III, et al. , “Dial-up switched 56,000 bits-per-second teleradiology system,” Proc. SPIE 1654, 97 (1992). 10.1117/12.60263 [DOI] [Google Scholar]
239.Cox J. R., Jr., et al. , “Demonstration of medical communications based on an ATM broadband network technology,” Proc. SPIE 1654, 44 (1992). 10.1117/12.60258 [DOI] [Google Scholar]
240.Stewart B. K., et al. , “Design of a high-speed high-resolution teleradiology system,” Proc. SPIE 1654, 66 (1992). 10.1117/12.60260 [DOI] [PubMed] [Google Scholar]
241.Mun S. K., et al. , “Command-wide teleradiology for US Armed Forces in Korea,” Proc. SPIE 1654, 81 (1992). 10.1117/12.60261 [DOI] [Google Scholar]
242.Blaine G. J., et al. , “Teleradiology support via a narrow band ISDN and the JPEG still image compression standard,” Proc. SPIE 1654, 545 (1992). 10.1117/12.60311 [DOI] [Google Scholar]
243.Taira R. K., et al. , “Design of a PACS cluster controller,” Proc. SPIE 1654, 203 (1992). 10.1117/12.60270 [DOI] [Google Scholar]
244.Ratib O. M., et al. , “Distributed architecture for image archival in a hospital-wide PACS,” Proc. SPIE 1654, 222 (1992). 10.1117/12.60273 [DOI] [Google Scholar]
245.Breant C. M., et al. , “Issues and solutions for interfacing a PACS database with a RIS,” Proc. SPIE 1654, 255 (1992). 10.1117/12.60277 [DOI] [Google Scholar]
246.Ottes F. P., et al. , “Prototyping a PACS-RIS/HIS interface in Europe,” Proc. SPIE 1654, 551 (1992). 10.1117/12.60312 [DOI] [Google Scholar]
247.Best D. E., et al. , “Update of the ACR-NEMA digital imaging and communications in medicine standard,” Proc. SPIE 1654, 356 (1992). 10.1117/12.60322 [DOI] [Google Scholar]
248.Bakker A. R., “Data protection and security issues of PACS,” Proc. SPIE 1654, 509 (1992). 10.1117/12.60306 [DOI] [Google Scholar]
249.Huda W., et al. , “Network-bandwidth and archive-storage requirements model for PACS,” Proc. SPIE 1899, 14 (1993). 10.1117/12.152885 [DOI] [Google Scholar]
250.McNeill K. M., et al. , “Experimental high-speed network,” Proc. SPIE 1899, 271 (1993). 10.1117/12.152891 [DOI] [Google Scholar]
251.Chen Y. P., Kim Y., “Cost-effective data storage/archival subsystem for functional PACS,” Proc. SPIE 1899, 131 (1993). 10.1117/12.152876 [DOI] [Google Scholar]
252.Wong A. W. K., Lou S. A., Huang H. K., “PAC subsystems performance: centralized versus distributive,” Proc. SPIE 1899, 24 (1993). 10.1117/12.152894 [DOI] [Google Scholar]
253.Andriole K. P., Ratib O. M., Huang H. K., “Picture archiving and communication system-to-personal computer radiologist workstation,” Proc. SPIE 1899, 90 (1993). 10.1117/12.152869 [DOI] [Google Scholar]
254.Lou S. A., et al. , “2K radiological image display station,” Proc. SPIE 1899, 95 (1993). 10.1117/12.152870 [DOI] [Google Scholar]
255.Honeyman J. C., et al. , “Functional requirements for diagnostic workstations,” Proc. SPIE 1899, 103 (1993). 10.1117/12.152871 [DOI] [Google Scholar]
256.Keen J., Bryan S., Weatherburn G. C., “Evaluation of PACS at Hammersmith Hospital: instrument for the assessment of the subjective views of clinical staff,” Proc. SPIE 1899, 463 (1993). 10.1117/12.152917 [DOI] [Google Scholar]
257.Mattheus R. A., “European standardization effort: interworking the goal,” Proc. SPIE 1899, 194 (1993). 10.1117/12.152883 [DOI] [Google Scholar]
258.Fritz S. L., Roys S. R., Munjal S., “Object-oriented ACR-NEMA data dictionary in C++,” Proc. SPIE 1899, 206 (1993). 10.1117/12.152884 [DOI] [Google Scholar]
259.Chimiak W. J., Williams R. C., “Translation of modality database entries to an ACR-NEMA transfer syntax,” Proc. SPIE 1899, 212 (1993). 10.1117/12.152886 [DOI] [Google Scholar]
260.Honeyman J. C., et al. , “Nuclear medicine PACS with an interfile/ACR-NEMA interface and on-line medical record interface,” Proc. SPIE 1899, 408 (1993). 10.1117/12.152909 [DOI] [Google Scholar]
261.More S. M., Blaine G. J., Jost R. G., “Performance observations based on a subset of the DICOM 3.0 draft-standard,” Proc. SPIE 1899, 218 (1993). 10.1117/12.152887 [DOI] [Google Scholar]
262.Jost R. G., “DICOM Version 3.0 demonstration at InfoRAD 1992,” Proc. SPIE 1899, 233 (1993). 10.1117/12.152862 [DOI] [Google Scholar]
263.Ottes F. P., et al. , “Functional specification of the HIPIN HIS/RIS-PACS interface,” Proc. SPIE 1899, 63 (1993). 10.1117/12.152860 [DOI] [Google Scholar]
264.Bartsch F. R., Gerneth M., Schosser R., “Videoconference for radiological expert consultation in the EC-project TELEMED,” Proc. SPIE 1899, 278 (1993). 10.1117/12.152892 [DOI] [Google Scholar]
265.Ligier Y., et al. , “Interactive software for cooperative medicine and remote consultations,” Proc. SPIE 1899, 318 (1993). 10.1117/12.152897 [DOI] [Google Scholar]
266.Willis C. E., et al. , “Evolution of teleradiology in the defense medical establishment,” Proc. SPIE 1899, 366 (1993). 10.1117/12.152903 [DOI] [Google Scholar]
267.Stewart B. K., et al. , “Technical development of shared-radiology educational resources via teleconferencing,” Proc. SPIE 1899, 284 (1993). 10.1117/12.152893 [DOI] [PubMed] [Google Scholar]
268.Whitman R. A., et al. , “Performance of a teleradiology medical doctor’s workstation supported by narrow-band integrated services digital networking,” Proc. SPIE 2165, 262 (1994). 10.1117/12.174310 [DOI] [Google Scholar]
269.Yu Y. P., et al. , “Analysis of joint photographic expert group (JPEG) compression on communications in a telepathology system,” Proc. SPIE 2165, 283 (1994). 10.1117/12.174313 [DOI] [Google Scholar]
270.Leckie R. G., et al. , “Clinical experience with teleradiology in the US military,” Proc. SPIE 2165, 301 (1994). 10.1117/12.174315 [DOI] [Google Scholar]
271.Bannerjee S., Kabuka M. R., “ATM-based fiber optic network for scalable and modular PACS design,” Proc. SPIE 2165, 218 (1994). 10.1117/12.174305 [DOI] [Google Scholar]
272.Frost M. M., et al. , “Medical information metropolitan area network,” Proc. SPIE 2165, 228 (1994). 10.1117/12.174306 [DOI] [Google Scholar]
273.Chen D. T., et al. , “Image flow management in a PACS network,” Proc. SPIE 2165, 233 (1994). 10.1117/12.174307 [DOI] [Google Scholar]
274.Yin L., et al. , “Use of personal computer technology in supporting a radiological review workstation,” Proc. SPIE 2165, 27 (1994). 10.1117/12.174323 [DOI] [Google Scholar]
275.Nishihara E., et al. , “Radiology information system/picture archiving and communication system architecture to assist daily practical reading at the Toshiba Hospital,” Proc. SPIE 2165, 172 (1994). 10.1117/12.174299 [DOI] [Google Scholar]
276.Honeyman-Buck J. C., Frost M. M., Staab E. V., “On-line medical record/RIS/PACS interface,” Proc. SPIE 2165, 172 (1994). 10.1117/12.174299 [DOI] [Google Scholar]
277.Kondoh H., et al. , “HIS-RIS-Modality-PACS integration in Osaka University,” Proc. SPIE 2165, 790 (1994). 10.1117/12.174373 [DOI] [Google Scholar]
278.Coumans K. O., Davenport K. G., “Implementation of a stand-alone optical archive: the benefits of PACS without the problems,” Proc. SPIE 2165, 78 (1994). 10.1117/12.174375 [DOI] [Google Scholar]
279.Wong A. W. K., et al. , “Automated prefetch mechanism: design and implementation for a radiology PACS,” Proc. SPIE 2165, 102 (1994). 10.1117/12.174293 [DOI] [Google Scholar]
280.Wilson D. L., Smith D. V., Rice B., “Intelligent prefetch strategies for historical images in a large PACS,” Proc. SPIE 2165, 112 (1994). 10.1117/12.174294 [DOI] [Google Scholar]
281.Sheng O. R. L., et al. , “Knowledge-based image retrieval: a new generation design,” Proc. SPIE 2165, 137 (1994). 10.1117/12.174296 [DOI] [Google Scholar]
282.Prior F. W., et al. , “DICOM user conformance profile: proof of concept,” Proc. SPIE 2165, 348 (1994). 10.1117/12.174320 [DOI] [Google Scholar]
283.Moore S. M., et al. , “Measured performance of DICOM-TCP and DICOM-ISO implementations,” Proc. SPIE 2165, 359 (1994). 10.1117/12.174321 [DOI] [Google Scholar]
284.Jensch P. F., et al. , “DICOM v3.0 – THE CEN trial implementation,” Proc. SPIE 2165, 368 (1994). 10.1117/12.174322 [DOI] [Google Scholar]
285.Kuzmak P. M., Dayhoff R. E., “Bidirectional ACR-NEMA interface between the VA’s DHCP integrated imaging system and the Siemens-Loral PACS,” Proc. SPIE 2165, 387 (1994). 10.1117/12.174325 [DOI] [PMC free article] [PubMed] [Google Scholar]
286.Lee J. K., et al. , “Adaptation of industry standards to PACS,” Proc. SPIE 2165, 397 (1994). 10.1117/12.174326 [DOI] [Google Scholar]
287.Frost M. M., Honeyman-Buck J. C., Staab E. V., “DICOM server for computed tomography and magnetic resonance acquisition to an archive,” Proc. SPIE 2165, 70 (1994). 10.1117/12.174365 [DOI] [Google Scholar]
288.Duerinckx A. J., et al. , “Evaluation and early medical experience with an ultrasound mini-PACS system at the VA Medical Center West Los Angeles,” Proc. SPIE 2165, 404 (1994). 10.1117/12.174327 [DOI] [Google Scholar]
289.Gustafson D. E., et al. , “Scalable ultrasound PACS: evolving needs for multimode ultrasound image and data management,” Proc. SPIE 2165, 418 (1994). 10.1117/12.174328 [DOI] [Google Scholar]
290.Georgiou M. F., et al. , “Multivendor nuclear medicine pacs provide fully digital clinical operation at the University of Miami Jackson Memorial Hospital,” Proc. SPIE 2165, 429 (1994). 10.1117/12.174329 [DOI] [Google Scholar]
291.Wilson A. J., et al. , “Digitization and remote transmission of magnetic resonance hard-copy images: a clinical comparison of original and soft-copy images,” Proc. SPIE 2165, 438 (1994). 10.1117/12.174330 [DOI] [Google Scholar]
292.van Gennip E. M. S. K., et al. , “TEASS: evaluation of PACS in three European hospitals: first results and recommendations,” Proc. SPIE 2165, 501 (1994). 10.1117/12.174339 [DOI] [Google Scholar]
293.Hangiandreou N. J., et al. , “Current status of the joint Mayo Clinic-IBM PACS project,” Proc. SPIE 2165, 519 (1994). 10.1117/12.174341 [DOI] [Google Scholar]
294.Huang H. K., et al. , “Second generation picture archiving and communication system,” Proc. SPIE 2165, 527 (1994). 10.1117/12.174342 [DOI] [Google Scholar]
295.Smith D. V., et al. , “Lessons learned and two years clinical experience in implementing the medical diagnostic imaging support (MDIS) system at Madigan Army Medical Center,” Proc. SPIE 2165, 538 (1994). 10.1117/12.174343 [DOI] [Google Scholar]
296.Langlotz C. P., et al. , “Methodology for the economic assessment of PACS,” Proc. SPIE 2165, 584 (1994). 10.1117/12.174348 [DOI] [Google Scholar]
297.Bryan S., et al. , “Technology assessment of PACS: measurement and analysis of radiologists’ reporting times when reporting from film,” Proc. SPIE 2165, 820 (1994). 10.1117/12.174378 [DOI] [Google Scholar]
298.Glicksman R. A., Prior F. W., “Image quality concepts for PACS,” Proc. SPIE 2165, 694 (1994). 10.1117/12.174360 [DOI] [Google Scholar]
299.Romlein J. R., et al. , “Transitioning process of a film-based radiology department to direct digital imaging,” Proc. SPIE 2165, 850 (1994). 10.1117/12.174382 [DOI] [Google Scholar]
300.Fritz S. L., et al. , “Implementing a DICOM-HL7 interface application,” Proc. SPIE 2435, 100 (1995). 10.1117/12.208764 [DOI] [Google Scholar]
301.Beaver S. M., Sippel-Schmidt T. M., “Approach to implementing a DICOM network: incorporate both economics and workflow adaptation,” Proc. SPIE 2435, 124 (1995). 10.1117/12.208767 [DOI] [Google Scholar]
302.Reynolds R. A., et al. , “Matching Images from digital modalities to exams scheduled via RIS or PACS,” Proc. SPIE 2435, 340 (1995). 10.1117/12.208794 [DOI] [Google Scholar]
303.Kuzmak P. M., Norton G. S., Dayhoff R. E., “Using experience with bidirectional HL7-ACR-NEMA interfaces between the Federal Government HIS/RIS and commercial PACS to plan for DICOM,” Proc. SPIE 2435, 132 (1995). 10.1117/12.208798 [DOI] [Google Scholar]
304.Meissner M. C., Levine B. A., Mun S. K., “RIS/HIS and PACS interfaces: evaluating the use of standards,” Proc. SPIE 2435, 462 (1995). 10.1117/12.208810 [DOI] [Google Scholar]
305.Fritz S. L., et al. , “C++ class library for DICOM services to support a HIS/RIS interface,” Proc. SPIE 2435, 462 (1995). 10.1117/12.208810 [DOI] [Google Scholar]
306.Huang H. K., et al. , “High-performance testbed network with ATM technology for neuroimaging,” Proc. SPIE 2435, 146 (1995). 10.1117/12.208768 [DOI] [Google Scholar]
307.Tohme W. G., et al. , “Evaluating the role of gigabit speed wide-area networks in remote medical treatment,” Proc. SPIE 2435, 166 (1995). 10.1117/12.208770 [DOI] [Google Scholar]
308.Lou S. A., et al. , “Interhospital CT image communication: T-1 line versus courier service,” Proc. SPIE 2435, 188 (1995). 10.1117/12.208773 [DOI] [Google Scholar]
309.Stewart B. K., Carter S. J., Rowberg A. H., “Application of the advanced communications technology satellite for teleradiology and telemedicine,” Proc. SPIE 2435, 210 (1995). 10.1117/12.208776 [DOI] [PMC free article] [PubMed] [Google Scholar]
310.Kim Y., et al. , “Seahawk: telemedicine project in the Pacific Northwest,” Proc. SPIE 2435, 232 (1995). 10.1117/12.208778 [DOI] [Google Scholar]
311.Morin R. L., Berquist T. H., Pietan J. H., “Clinically oriented evaluation of family practice teleradiology,” Proc. SPIE 2435, 239 (1995). 10.1117/12.208779 [DOI] [Google Scholar]
312.Tohme W. G., et al. , “Project RavenCare: global multimedia telemedicine in Alaska,” Proc. SPIE 2435, 519 (1995). 10.1117/12.208817 [DOI] [Google Scholar]
313.Shile P. E., Friedland J. A., Wilson A. J., “Radiologists’ acceptance of teleradiology: responses to surveys in 1990 and 1994,” Proc. SPIE 2435, 196 (1995). 10.1117/12.208774 [DOI] [Google Scholar]
314.Horii S. C., et al. , “Use of mini-PACS technology in ultrasound: the potential for productivity improvement,” Proc. SPIE 2435, 257 (1995). 10.1117/12.208783 [DOI] [Google Scholar]
315.Dwyer S. J., III, et al. , “Evaluation of a PACS for CT and MR: film compared to PACS,” Proc. SPIE 2435, 268 (1995). 10.1117/12.208785 [DOI] [Google Scholar]
316.Lindhardt F. E., “PACS – The Viborg project: clinical experiences with a totally digitalized hospital,” Proc. SPIE 2435, 312 (1995). 10.1117/12.208790 [DOI] [Google Scholar]
317.Mosser H. M., Paertan G., Hruby W., “Clinical routine operation of a filmless radiology department: three years experience,” Proc. SPIE 2435, 321 (1995). 10.1117/12.208791 [DOI] [Google Scholar]
318.Wong A. W. K., Huang H. K., Arenson R. L., “Hierarchical image storage management: design and implementation for a distributed PACS,” Proc. SPIE 2435, 61 (1995). 10.1117/12.208826 [DOI] [Google Scholar]
319.He Y., et al. , “Fault tolerance techniques to assure data integrity in high-volume PACS image archives,” Proc. SPIE 2435, 378 (1995). 10.1117/12.208799 [DOI] [Google Scholar]
320.Behlen F. M., Hoffman K. R., MacMahon Heber, “Long-term strategies for PACS archive design,” Proc. SPIE 2711, 2 (1996). 10.1117/12.239233 [DOI] [Google Scholar]
321.Frost M. M., Honeyman-Buck J. C., Staab E. V., “PACS Archive strategy utilizing a 3TB Jukebox,” Proc. SPIE 2711, 22 (1996). 10.1117/12.239264 [DOI] [Google Scholar]
322.Van M. D., Humphrey L. M., Ravin C. E., “Development of a high-performance image server Using ATM-technology,” Proc. SPIE 2711, 9 (1996). 10.1117/12.239242 [DOI] [Google Scholar]
323.Lee J. K., et al. , “ATM-distributed PACS server for ICU application,” Proc. SPIE 2711, 14 (1996). 10.1117/12.239253 [DOI] [Google Scholar]
324.Duerinckx A. J., et al. , “Assessment of asynchronous transfer mode (ATM) networks for regional teleradiology,” Proc. SPIE 2711, 61 (1996). 10.1117/12.239298 [DOI] [Google Scholar]
325.Steward B. K., et al. , “Real-time compressed video ultrasound using the advanced communications technology satellite,” Proc. SPIE 2711, 194 (1996). 10.1117/12.239248 [DOI] [PMC free article] [PubMed] [Google Scholar]
326.Gnoyke H., “Standards for the integration of modalities with information systems and IMAC systems based on DICOM/MEDICOM supplements,” Proc. SPIE 2711, 72 (1996). 10.1117/12.239234 [DOI] [Google Scholar]
327.Chimiak W. J., “Preliminary DICOM acceptance testing using the central test node,” Proc. SPIE 2711, 82 (1996). 10.1117/12.239235 [DOI] [Google Scholar]
328.Moore S. M., “Observations on DICOM demonstrations at the RSNA annual meetings,” Proc. SPIE 2711, 89 (1996). 10.1117/12.239236 [DOI] [Google Scholar]
329.Grevera G. J., Feingold E. R., Horii S. C., “WWW to DICOM interface,” Proc. SPIE 2711, 109 (1996). 10.1117/12.239238 [DOI] [Google Scholar]
330.Honeyman-Buck J. C., et al. , “RIS requirements to support a PACS infrastructure,” Proc. SPIE 2711, 120 (1996). 10.1117/12.239239 [DOI] [Google Scholar]
331.Enning C. J. W. A., et al. , “Evaluation of a multimedia information system for endoscopy,” Proc. SPIE 2711, 205 (1996). 10.1117/12.239249 [DOI] [Google Scholar]
332.van Poppel B. M., et al. , “Endoscopy PACS integrated with the HIS,” Proc. SPIE 2711, 483 (1996). 10.1117/12.239283 [DOI] [Google Scholar]
333.Lobodzzinski S. S., Maurer H., “Hypermedia network architecture for digital echocardiography,” Proc. SPIE 2711, 214 (1996). 10.1117/12.239250 [DOI] [Google Scholar]
334.Barnett B. G., et al. , “Satellite teleradiology test bed for digital mammography,” Proc. SPIE 2711, 308 (1996). 10.1117/12.239263 [DOI] [Google Scholar]
335.So G. J., et al. , “First international telemedicine trial to China using the internet,” Proc. SPIE 2711, 327 (1996). 10.1117/12.239266 [DOI] [Google Scholar]
336.Huang H. K., et al. , “Current status of the UCSF second-generation PACS,” Proc. SPIE 2711, 364 (1996). 10.1117/12.239270 [DOI] [Google Scholar]
337.Morin R. L., Berquist T. H., Rueger W., “Mayo Clinic Jacksonville electronic radiology practice,” Proc. SPIE 2711, 384 (1996). 10.1117/12.239272 [DOI] [Google Scholar]
338.Toshimitsu A., et al. , “Toshiba General Hospital PACS for routine in- and outpatient clinics,” Proc. SPIE 2711, 466 (1996). 10.1117/12.239281 [DOI] [Google Scholar]
339.Jeromin L. S., et al. , “Productivity improvements with a direct digital radiography system integrated with PACS,” Proc. SPIE 2711, 236 (1996). 10.1117/12.239255 [DOI] [Google Scholar]
340.Melson D. L., et al. , “Methodology for cost analysis of film-based and filmless portable chest systems,” Proc. SPIE 2711, 400 (1996). 10.1117/12.239273 [DOI] [Google Scholar]
341.Andriole K. P., et al. , “Clinical comparison of CR and screen film for imaging the critically Ill neonate,” Proc. SPIE 2711, 281 (1996). 10.1117/12.239259 [DOI] [Google Scholar]
342.Andriole K. P., et al. , “Impact and utilization studies of a PACS display station in an ICU setting,” Proc. SPIE 2711, 286 (1996). 10.1117/12.239260 [DOI] [Google Scholar]
343.Horii S. C., et al. , “PACS workstation functions: usage differences between radiologists and MICU physicians,” Proc. SPIE 2711, 266 (1996). 10.1117/12.239257 [DOI] [Google Scholar]
344.Huang H. K., Lou S. A., Wong A. W. K., “PACS pitfalls and bottlenecks,” Proc. SPIE 3035, 2 (1997). 10.1117/12.274553 [DOI] [Google Scholar]
345.Horii S. C., et al. , “What do we need to advance PACS workstations: a critical review with suggestions,” Proc. SPIE 3035, 6 (1997). 10.1117/12.274562 [DOI] [Google Scholar]
346.Kim J. H., et al. , “HIS/RIS/pacs integration toward total hospital information system,” Proc. SPIE 3035, 20 (1997). 10.1117/12.274583 [DOI] [Google Scholar]
347.Alsafadi Y. H., Lord W. P., Mankovich N. H., “Enterprise communication framework as a means to PACS/information systems interoperability,” Proc. SPIE 3035, 29 (1997). 10.1117/12.274592 [DOI] [PubMed] [Google Scholar]
348.Siegel E. L., et al. , “Analysis of the clinical impact of a DICOM HIS/RIS to modality interface and recommendations for improvement,” Proc. SPIE 3035, 146 (1997). 10.1117/12.274564 [DOI] [Google Scholar]
349.Kuzmak P. M., Dayhoff R. E., “Experience with MUMPS-based DICOM interfaces between the department of veterans affairs HIS/RIS and commercial vendors,” Proc. SPIE 3035, 134 (1997). 10.1117/12.274563 [DOI] [Google Scholar]
350.Wong A. W. K., Huang H. K., Arenson R. L., “Adaptation of DICOM to an operational PACS,” Proc. SPIE 3035, 153 (1997). 10.1117/12.274566 [DOI] [Google Scholar]
351.Behlen F. M., et al. , “Radiology information system control of a DICOM-based PACS,” Proc. SPIE 3035, 159 (1997). 10.1117/12.274567 [DOI] [Google Scholar]
352.Clunie D. A., “Progress in extending DICOM to media interchange,” Proc. SPIE 3035, 495 (1997). 10.1117/12.274606 [DOI] [Google Scholar]
353.Feingold E. R., et al. , “Web-based radiology applications for clinicians and radiologists,” Proc. SPIE 3035, 60 (1997). 10.1117/12.274630 [DOI] [Google Scholar]
354.Przybylowicz J. E., “Enterprise imaging and display consistency,” Proc. SPIE 3035, 595 (1997). 10.1117/12.274622 [DOI] [Google Scholar]
355.Hayrapetian A. S., et al. , “Workstation and network needs for very large PACS implementation,” Proc. SPIE 3035, 291 (1997). 10.1117/12.274610 [DOI] [Google Scholar]
356.Dai H. L., et al. , “Breaking the bottleneck: high-speed medical image transmission through ATM network: implementation and application,” Proc. SPIE 3035, 108 (1997). 10.1117/12.274558 [DOI] [Google Scholar]
357.Whitman R. A., et al. , “Management of ATM-based networks supporting multimedia medical information systems,” Proc. SPIE 3035, 113 (1997). 10.1117/12.274559 [DOI] [Google Scholar]
358.Siegel E. L., et al. , “Three and a half years’ experience with PACS at the Baltimore VA Medical Center,” Proc. SPIE 3035, 15 (1997). 10.1117/12.274573 [DOI] [Google Scholar]
359.Duerinckx A. J., et al. , “Teleradiology for Veterans Integrated Service Networks,” Proc. SPIE 3035, 124 (1997). 10.1117/12.274561 [DOI] [Google Scholar]
360.Cleary K. R., et al. , “Teleradiology network to improve patient care in a peacekeeping military operation,” Proc. SPIE 3035, 222 (1997). 10.1117/12.274575 [DOI] [Google Scholar]
361.Kim J. H., et al. , “Development of hospital-integrated large-scale PACS in Seoul National University Hospital,” Proc. SPIE 3035, 248 (1997). 10.1117/12.274578 [DOI] [Google Scholar]
362.Wilson D. L., “Filmless radiology at Brooke Army Medical Center,” Proc. SPIE 3035, 256 (1997). 10.1117/12.274579 [DOI] [Google Scholar]
363.Krupinski E. A., Hopper L., “Teleradiology in rural Arizona: user’s perspective,” Proc. SPIE 3035, 350 (1997). 10.1117/12.274590 [DOI] [Google Scholar]
364.Hu D., et al. , “Engineering and clinical-oriented solution to cost-effective PACS for developing areas in China,” Proc. SPIE 3035, 552 (1997). 10.1117/12.274615 [DOI] [Google Scholar]
365.Behlen F. M., et al. , “Multiresolution storage in a PACS archive,” Proc. SPIE 3035, 39 (1997). 10.1117/12.274601 [DOI] [Google Scholar]
366.Chunn T., “Archival storage solutions for PACS,” Proc. SPIE 3035, 47 (1997). 10.1117/12.274620 [DOI] [Google Scholar]
367.Collmann J. R., et al. , “Comparing the security risks of paper-based and computerized patient record systems,” Proc. SPIE 3035, 172 (1997). 10.1117/12.274569 [DOI] [Google Scholar]
368.Meissner M. C., et al. , “Protecting clinical data in PACS, teleradiology systems and research environments,” Proc. SPIE 3035, 183 (1997). 10.1117/12.274570 [DOI] [Google Scholar]
369.Thiel A., et al. , “Telemedicine with integrated data security in ARM-based networks,” Proc. SPIE 3035, 191 (1997). 10.1117/12.274571 [DOI] [Google Scholar]
370.Zhang J., Andriole K. P., Huang H. K., “Computed radiographic image postprocessing in picture archiving and communication systems,” Proc. SPIE 3035, 310 (1997). 10.1117/12.274585 [DOI] [Google Scholar]
371.Andriole K. P., Gould R. G., Arenson R. L., “Computed radiography in an emergency department setting,” Proc. SPIE 3035, 389 (1997). 10.1117/12.274595 [DOI] [Google Scholar]
372.Reiker G. G., et al. , “Filmless digital chest radiography within the radiology department,” Proc. SPIE 3035, 355 (1997). 10.1117/12.274591 [DOI] [Google Scholar]
373.Lou S. A., et al. , “Full-field direct digital telemammography: preliminary,” Proc. SPIE 3035, 369 (1997). 10.1117/12.274593 [DOI] [PubMed] [Google Scholar]
374.Dostalova T., Smutny V., “Dental archives based on images,” Proc. SPIE 3035, 464 (1997). 10.1117/12.274602 [DOI] [Google Scholar]
375.Pratt H. M., et al. , “Incremental cost of a department-wide PACS/CR implementation,” Proc. SPIE 3035, 413 (1997). 10.1117/12.274598 [DOI] [Google Scholar]
376.Reiner B. I., et al. , “Impact of filmless operation on staff productivity in the CT Department,” Proc. SPIE 3035, 431 (1997). 10.1117/12.274600 [DOI] [Google Scholar]
377.Wreder K., Nararro E., “PACS as an element of the computerized patient record: a health care enterprise model,” Proc. SPIE 3035, 445 (1997). 10.1117/12.274628 [DOI] [Google Scholar]
378.Chacko A. K., Lollar H. W., “Proposal for an information revolution in imaging in healthcare: the dawn of the new millenium,” Proc. SPIE 3035, 455 (1997). 10.1117/12.274629 [DOI] [Google Scholar]
379.Chimiak W. J., Boehme J. M., “Fault tolerant high-performance PACS network design and implementation,” Proc. SPIE 3339, 2 (1998). 10.1117/12.319758 [DOI] [Google Scholar]
380.Blume H. R., et al. , “Scalability, performance and fault tolerance of PACS architectures,” Proc. SPIE 3339, 112 (1998). 10.1117/12.319760 [DOI] [Google Scholar]
381.Komo D., et al. , “DICOM implementation on online tape library storage system,” Proc. SPIE 3339, 105 (1998). 10.1117/12.319759 [DOI] [Google Scholar]
382.Thiel A., et al. , “Security concepts in clinical applications using DICOM,” Proc. SPIE 3339, 11 (1998). 10.1117/12.319767 [DOI] [Google Scholar]
383.Daniell A. L., Jin M. Y., Valentino D. J., “Clinical evaluation of high-performance lossless image compression,” Proc. SPIE 3339, 39 (1998). 10.1117/12.319798 [DOI] [Google Scholar]
384.Horii S. C., et al. , “Prototype controls for a plain radiography workstation,” Proc. SPIE 3339, 87 (1998). 10.1117/12.319822 [DOI] [Google Scholar]
385.Zhang J., et al. , “Real-time teleconsultation with high-resolution and large-volume medical imaging,” Proc. SPIE 3339, 185 (1998). 10.1117/12.319768 [DOI] [PubMed] [Google Scholar]
386.Telepak R. J., et al. , “Five years’ experience in a (really) rural teleradiology practice: was it worth it? The successes and failures,” Proc. SPIE 3339, 192 (1998). 10.1117/12.319769 [DOI] [Google Scholar]
387.Chacko A. K., et al. , “Vision and benefits of a virtual radiology environment for the US Army,” Proc. SPIE 3339, 200 (1998). 10.1117/12.319770 [DOI] [Google Scholar]
388.Duerinckx A. J., et al. , “First six months of clinical usage of an ATM network link between two Veterans Affairs Medical Centers,” Proc. SPIE 3339, 226 (1998). 10.1117/12.319773 [DOI] [Google Scholar]
389.Siegel E. L., Reiner B. I., Protopapas Z., “Evaluation of PACS in a multihospital environment,” Proc. SPIE 3339, 226 (1998). 10.1117/12.319773 [DOI] [Google Scholar]
390.Smith E. M., et al. , “Project MICAS: a multivendor open-system incremental approach to implementing an integrated enterprise-wide PACS: works in progress,” Proc. SPIE 3339, 457 (1998). 10.1117/12.319801 [DOI] [Google Scholar]
391.Erickson B. J., et al. , “Clinician image review patterns in an outpatient setting,” Proc. SPIE 3339, 406 (1998). 10.1117/12.319794 [DOI] [Google Scholar]
392.Langer S. G., Stewart B. K., “Implementation of an HL7/DICOM broker for automated patient demographic data entry in computed radiography systems,” Proc. SPIE 3339, 556 (1998). 10.1117/12.319815 [DOI] [Google Scholar]
393.Melson D. L., et al. , “Impact of a voice recognition system on report cycle time and radiologist reading time,” Proc. SPIE 3339, 226 (1998). 10.1117/12.319773 [DOI] [Google Scholar]
394.Strickland N. H., et al. , “Implementation of a major hardware and software upgrade in a hospital-wide PACS during clinical use,” Proc. SPIE 3339, 496 (1998). 10.1117/12.319806 [DOI] [Google Scholar]
395.Thiel A., et al. , “Security extensions to DICOM,” Proc. SPIE 3662, 72 (1999). 10.1117/12.352780 [DOI] [Google Scholar]
396.Zhou X., Lou S. A., Huang H. K., “Authenticity and integrity of digital mammographic images,” Proc. SPIE 3662, 138 (1999). 10.1117/12.352736 [DOI] [Google Scholar]
397.DeJarnette W. T., et al. , “Standards-based distributed PACS architecture,” Proc. SPIE 3662, 37 (1999). 10.1117/12.352764 [DOI] [Google Scholar]
398.Stewart B. K., Langer S. G., Martin K. P., “Integration of multiple DICOM web servers into an enterprise-wide web-based electronic medical record,” Proc. SPIE 3662, 52 (1999). 10.1117/12.352772 [DOI] [Google Scholar]
399.Clunie D. A., “Designing and implementing a PACS-aware DICOM image object for digital x-ray, mammography and intraoral applications,” Proc. SPIE 3662, 83 (1999). 10.1117/12.352730 [DOI] [Google Scholar]
400.Romlein J. R., et al. , “PACS: acceptance test, quality control, warranty, and maintenance continuum,” Proc. SPIE 3662, 111 (1999). 10.1117/12.352733 [DOI] [Google Scholar]
401.Siegel E. L., Reiner B. I., Cadogan M., “Frequency and failure of high-resolution monitors in a filmless imaging department,” Proc. SPIE 3662, 248 (1999). 10.1117/12.352751 [DOI] [PMC free article] [PubMed] [Google Scholar]
402.McNeill K. M., Holcomb M. J., Ovitt T. W., “Integrating LAN/WAN technologies in support of multimedia telemedicine and teleradiology,” Proc. SPIE 3662, 156 (1999). 10.1117/12.352738 [DOI] [Google Scholar]
403.Wong A. W. K., Huang H. K., “High-performance image storage and communications with fiber channel technology for PACS,” Proc. SPIE 3662, 163 (1999). 10.1117/12.352740 [DOI] [Google Scholar]
404.Honeyman-Buck J. C., Frost M. M., Drane W. E., “Expanding the PACS archive to support clinical review, research and education missions,” Proc. SPIE 3662, 171 (1999). 10.1117/12.352741 [DOI] [Google Scholar]
405.Persons K. R., et al. , “JPEG/wavelet ultrasound compression study,” Proc. SPIE 3662, 232 (1999). 10.1117/12.352750 [DOI] [Google Scholar]
406.Huang H. K., et al. , “Digital hand atlas for bone age assessment of children: an application of PACS database,” Proc. SPIE 3662, 178 (1999). 10.1117/12.352742 [DOI] [Google Scholar]
407.Andriole K. P., et al. , “CR softcopy display presets based on optimum visualization of specific findings,” Proc. SPIE 3662, 264 (1999). 10.1117/12.352753 [DOI] [Google Scholar]
408.Zhang J., et al. , “CR image background removal: a collection of interesting cases,” Proc. SPIE 3662, 377 (1999). 10.1117/12.352769 [DOI] [Google Scholar]
409.Gitlin J. N., Drinkard M., “CCD versus laser: a comparative study of two types of X-ray film digitizers,” Proc. SPIE 3662, 438 (1999). 10.1117/12.352778 [DOI] [Google Scholar]
410.Reiner B. I., Siegel E. L., Rostenberg B., “Redesigning the PACS reading room: optimizing monitor and room lighting,” Proc. SPIE 3662, 276 (1999). 10.1117/12.352756 [DOI] [Google Scholar]
411.Horii S. C., et al. , “Replacing film with PACS: work shifting and lack of automation,” Proc. SPIE 3662, 317 (1999). 10.1117/12.352761 [DOI] [Google Scholar]
412.Dwyer S. J., III, “A personalized view of the history of PACS in the USA,” Proc. SPIE 3980, 2 (2000). 10.1117/12.386388 [DOI] [Google Scholar]
413.Lemke H. U., et al. , “Early developments of PACS in Europe,” Proc. SPIE 3980, 12 (2000). 10.1117/12.386396 [DOI] [Google Scholar]
414.Gell G., “PACS-Graz 1985-2000: from a scientific pilot to a state-wide multimedia radiological information system,” Proc. SPIE 3980, 19 (2000). 10.1117/12.386405 [DOI] [Google Scholar]
415.Huang H. K., “PACS implementation experiences: from in-house to partnerships to advisory board,” Proc. SPIE 3980, 124 (2000). 10.1117/12.386394 [DOI] [Google Scholar]
416.Siegel E. L., Reiner B. I., Kuzmak P. M., “Adoption of PACS by the Department of Veterans Affairs: the past, the present and future plans,” Proc. SPIE 3980, 134 (2000). 10.1117/12.386395 [DOI] [Google Scholar]
417.Chacko A. K., et al. , “PACS implementation in the US Department of Defense,” Proc. SPIE 3980, 139 (2000). 10.1117/12.386397 [DOI] [Google Scholar]
418.Channin D. S., Hawkins R. C., Enzmann D. R., “North-by-northwesters: initial experience with PACS at Northwestern Memorial Hospital,” Proc. SPIE 3980, 275 (2000). 10.1117/12.386414 [DOI] [Google Scholar]
419.Kim H. J., et al. , “Design of a full PACS with experiences of mini-PACS in Yonsei University Medical Center,” Proc. SPIE 3980, 312 (2000). 10.1117/12.386417 [DOI] [Google Scholar]
420.Olges N. H., et al. , “Integrating JPEG compression with DICOM: experiences and technical issues,” Proc. SPIE 3980, 46 (2000). 10.1117/12.386440 [DOI] [Google Scholar]
421.Clunie D. A., “Lossless compression of grayscale medical images: effectiveness of traditional and state-of-the-art approaches,” Proc. SPIE 3980, 74 (2000). 10.1117/12.386389 [DOI] [Google Scholar]
422.DH Foos, et al. , “JPEG 2000 compression of medical imagery,” Proc. SPIE 3980, 85 (2000). 10.1117/12.386390 [DOI] [Google Scholar]
423.Andriole K. P., Hovanes M. E., Rowberg A. H., “Clinical utility of wavelet compression for resolution-enhanced chest radiography,” Proc. SPIE 3980, 107 (2000). 10.1117/12.386392 [DOI] [Google Scholar]
424.Chen C. W., et al. , “Wavelet-based compression of pathological images for telemedicine applications,” Proc. SPIE 3980, 113 (2000). 10.1117/12.386393 [DOI] [Google Scholar]
425.Cho Y. H., et al. , “Implementation of the test station for vendors’ equipment with DICOM 3.0,” Proc. SPIE 3980, 68 (2000). 10.1117/12.386442 [DOI] [Google Scholar]
426.Romlein J. R., et al. , “PACS: moving a live PACS with zero downtime,” Proc. SPIE 3980, 266 (2000). 10.1117/12.386413 [DOI] [Google Scholar]
427.Meyers J. A., “PACS: from planning to implementation for a new hospital facility,” Proc. SPIE 4323, 1 (2001). 10.1117/12.435474 [DOI] [Google Scholar]
428.Vogl R., “Going all digital in a University Hospital: a unified large-scale PACS for multiple departments and hospitals,” Proc. SPIE 4323, 7 (2001). 10.1117/12.435481 [DOI] [Google Scholar]
429.Chan L. W., Hartzman S., Trambert M., “Successful PACS at a community hospital,” Proc. SPIE 4323, 57 (2001). 10.1117/12.435456 [DOI] [Google Scholar]
430.Zhang J., et al. , “Design and implementation of picture archiving and communication system in Huadong Hospital,” Proc. SPIE 4323, 73 (2001). 10.1117/12.435459 [DOI] [Google Scholar]
431.Bao J., Gao J., “PACS development in China and the component PACS system,” Proc. SPIE 4323, 380 (2001). 10.1117/12.435504 [DOI] [Google Scholar]
432.Andriole K. P., Luth D. M., Gould R. G., “Workflow comparison of DR and screen-film dedicated chest systems,” Proc. SPIE 4323, 203 (2001). 10.1117/12.435477 [DOI] [Google Scholar]
433.Huda W., et al. , “Clinical performance of a prototype flat-panel digital detector for general radiography,” Proc. SPIE 4323, 397 (2001). 10.1117/12.435506 [DOI] [Google Scholar]
434.Blume H. R., et al. , “Practical aspects of grayscale calibration of display systems,” Proc. SPIE 4323, 28 (2001). 10.1117/12.435509 [DOI] [Google Scholar]
435.Siegel E. L., et al. , “Effect of monitor image quality on the soft-copy interpretation of chest CR images,” Proc. SPIE 4323, 42 (2001). 10.1117/12.435510 [DOI] [Google Scholar]
436.Riesmeier J., et al. , “DICOM image display consistency: a test environment,” Proc. SPIE 4323, 47 (2001). 10.1117/12.435511 [DOI] [Google Scholar]
437.Clunie D. A., “DICOM structured reporting: an object model as an implementation boundary,” Proc. SPIE 4323, 207 (2001). 10.1117/12.435478 [DOI] [Google Scholar]
438.Alberts C. J., Dorofee A., “HIPAA and information security risk: implementing an enterprise-wide risk management strategy,” Proc. SPIE 4323, 97 (2001). 10.1117/12.435462 [DOI] [Google Scholar]
439.Sostrom S., Collmann J. R., “Reviewing and reforming policy in health enterprise information security,” Proc. SPIE 4323, 118 (2001). 10.1117/12.435464 [DOI] [Google Scholar]
440.Collmann J. R., “HIPAA and the military health system: organizing technological and organizational reform in large enterprises,” Proc. SPIE 4323, 126 (2001). 10.1117/12.435465 [DOI] [Google Scholar]
441.Parisot C. R., et al. , “Management and presentation of grouped procedures: has the IHE integration profile cracked the toughest radiology workflow nut?” Proc. SPIE 4323, 192 (2001). 10.1117/12.435476 [DOI] [Google Scholar]
442.Brown M. J. G., et al. , “Assessing imaging procedure results outside the imaging department: a simple well-tried format,” Proc. SPIE 4323, 278 (2001). 10.1117/12.435490 [DOI] [Google Scholar]
443.Siegel E. L., Reiner B. I., “Clinical challenges associated with incorporation of nonradiology images into the electronic medical record,” Proc. SPIE 4323, 287 (2001). 10.1117/12.435492 [DOI] [Google Scholar]
444.Shani U., “Maintaining a legal status for filmless archived digital medical images,” Proc. SPIE 4323, 109 (2001). 10.1117/12.435463 [DOI] [Google Scholar]
445.Honeyman-Buck J. C., Arreola M., Frost M. M., “PACS according to Murphy: what can and will go wrong,” Proc. SPIE 4685, 7 (2002). 10.1117/12.466998 [DOI] [Google Scholar]
446.Horii S. C., et al. , “PACS technologies and reliability: are we making things better or worse?” Proc. SPIE 4685, 16 (2002). 10.1117/12.467007 [DOI] [Google Scholar]
447.Zhang J., et al. , “Automatic monitoring system for PACS management and operation,” Proc. SPIE 4685, 348 (2002). 10.1117/12.467026 [DOI] [Google Scholar]
448.Kennedy R. L., Seibert J. A., “Error component analysis for PACS: operational sources of data error in real world PACS for DICOM series, study and patient level identifiers,” Proc. SPIE 4685, 206 (2002). 10.1117/12.467009 [DOI] [Google Scholar]
449.Choi H. S., “Evolution of filmless PACS in Korea,” Proc. SPIE 4685, 42 (2002). 10.1117/12.467039 [DOI] [Google Scholar]
450.Kim H. J., “PACS industry in Korea,” Proc. SPIE 4685, 50 (2002). 10.1117/12.467040 [DOI] [Google Scholar]
451.Kim J. H., “Technical aspects of PACS in Korea,” Proc. SPIE 4685, 58 (2002). 10.1117/12.467041 [DOI] [Google Scholar]
452.Lim H. W., et al. , “Full PACS installation in Seoul National University Hospital Korea,” Proc. SPIE 4685, 75 (2002). 10.1117/12.466991 [DOI] [Google Scholar]
453.Lim J. H., “Cost justification of filmless PACS and national policy,” Proc. SPIE 4685, 72 (2002). 10.1117/12.466990 [DOI] [Google Scholar]
454.Suh E. B., et al. , “Web-based medical image archive,” Proc. SPIE 4685, 31 (2002). 10.1117/12.467027 [DOI] [Google Scholar]
455.Liu B. J., et al. , “PACS archive upgrade and data migration: clinical experiences,” Proc. SPIE 4685, 83 (2002). 10.1117/12.466992 [DOI] [Google Scholar]
456.Whang T., et al. , “Financial and workflow analysis of radiology reporting processes in the planning phase of implementation of a speech recognition system,” Proc. SPIE 4685, 168 (2002). 10.1117/12.467003 [DOI] [Google Scholar]
457.Moise A., Atkins M. S., “Workflow oriented hanging protocols for radiology workstation,” Proc. SPIE 4685, 189 (2002). 10.1117/12.467006 [DOI] [Google Scholar]
458.Kuzmak P. M., Dayhoff R. E., “Extending DICOM imaging to new clinical specialties in the healthcare enterprise,” Proc. SPIE 4685, 233 (2002). 10.1117/12.467012 [DOI] [Google Scholar]
459.Park H. J., et al. , “IHE Year 3 demonstration participation at RSNA 2001: image manager, image archive and MPPS manager,” Proc. SPIE 4685, 398 (2002). 10.1117/12.467033 [DOI] [Google Scholar]
460.Ha D. H., et al. , “Effectiveness of wireless communication using 100Mbps infrared in PACS,” Proc. SPIE 4685, 391 (2002). 10.1117/12.467032 [DOI] [Google Scholar]
461.Eichelberg M., et al. , “IHE Europe: extending the IHE initiative to the European healthcare market,” Proc. SPIE 5033, 1 (2003). 10.1117/12.480660 [DOI] [Google Scholar]
462.Nagy P. G., Warnock M., Evans D., “Predicting PACS loading and performance metrics using Monte Carlo and queuing methods,” Proc. SPIE 5033, 48 (2003). 10.1117/12.480469 [DOI] [Google Scholar]
463.Chan L. W. C., et al. , “International Internet2 connectivity requirements for tele-imaging consultation,” Proc. SPIE 5033, 172 (2003). 10.1117/12.481941 [DOI] [Google Scholar]
464.Slik S., Montour M., Altman T., “Comprehensive security framework for the communication and storage of medical images,” Proc. SPIE 5033, 212 (2003). 10.1117/12.480475 [DOI] [Google Scholar]
465.Horii S. C., “DIOM image viewers: a survey,” Proc. SPIE 5033, 251 (2003). 10.1117/12.487803 [DOI] [Google Scholar]
466.Long L. R., et al. , “Biomedical information from a national collection of spine X-rays: film to content-based retrieval,” Proc. SPIE 5033, 70 (2003). 10.1117/12.487798 [DOI] [Google Scholar]
467.Pavlopoulou C., Kak A. C., Brodley C. E., “Content-based image retrieval for medical imagery,” Proc. SPIE 5033, 85 (2003). 10.1117/12.487802 [DOI] [Google Scholar]
468.Ghebreab S., Jaffe C., Smeulders A. W. M., “Concept-based retrieval of biomedical images,” Proc. SPIE 5033, 97 (2003). 10.1117/12.487796 [DOI] [Google Scholar]
469.Nagaraj N., et al. , “Region of interest and windowing-based progressive medical image delivery using JPEG2000,” Proc. SPIE 5033, 382 (2003). 10.1117/12.480467 [DOI] [Google Scholar]
470.Lee J., Kim H. J., Yoo H. S., “Development of effective compression for CT series,” Proc. SPIE 5033, 424 (2003). 10.1117/12.480657 [DOI] [Google Scholar]
471.Shen S. Z., et al. , “PACS archive server database structure enabling flexible queries,” Proc. SPIE 5033, 370 (2003). 10.1117/12.480461 [DOI] [Google Scholar]
472.Mongkolwat P., et al. , “Pathology tickler: an HL7 monitoring system to provide clinical feedback,” Proc. SPIE 5033, 281 (2003). 10.1117/12.480671 [DOI] [Google Scholar]
473.Andriole K. P., et al. , “Transforming the radiological interpretation process: the SCAR TRIP initiative,” Proc. SPIE 5371, 1 (2004). 10.1117/12.543741 [DOI] [Google Scholar]
474.O’Donnell K., “Update on the IHE initiative,” Proc. SPIE 5371, 52 (2004). 10.1117/12.543744 [DOI] [Google Scholar]
475.Eichelberg M., et al. , “Ten years of medical imaging standardization and prototypical implementation; the DICOM standard and the OFFIS DICOM Toolkit (DCMTK),” Proc. SPIE 5371, 57 (2004). 10.1117/12.534853 [DOI] [Google Scholar]
476.Samei E., Wright S. L., “Effect of viewing angle response on DICOM compliance of liquid crystal displays,” Proc. SPIE 5371, 170 (2004). 10.1117/12.536198 [DOI] [Google Scholar]
477.Krishnan K., et al. , “Compression/decompression strategies for large-volume medical imagery,” Proc. SPIE 5371, 152 (2004). 10.1117/12.535650 [DOI] [Google Scholar]
478.Zhou G., et al. , “Content-based cell pathology image retrieval by combining different features,” Proc. SPIE 5371, 326 (2004). 10.1117/12.532926 [DOI] [Google Scholar]
479.Dos Santos M., Furuie S. S., “High-performance web viewer for cardiac images,” Proc. SPIE 5371, 391 (2004). 10.1117/12.535838 [DOI] [Google Scholar]
480.Moise A., Atkins M. S., “Interaction techniques for radiology workstations: impact on users’ productivity,” Proc. SPIE 5371, 16 (2004). 10.1117/12.534468 [DOI] [Google Scholar]
481.Sappington R. W., “Adoption and resistance: reflections on human, organizational and information technologies in PACS,” Proc. SPIE 5748, 1 (2005). 10.1117/12.596042 [DOI] [Google Scholar]
482.Martinex-Martinez A., et al. , “A strategy for PACS development using introductory team software process,” Proc. SPIE 5748, 10 (2005). 10.1117/12.596088 [DOI] [Google Scholar]
483.Ratib O., et al. , “Navigating the fifth dimension: new concepts in interactive multimodality and multidimensional image navigation,” Proc. SPIE 5748, 28 (2005). 10.1117/12.594648 [DOI] [Google Scholar]
484.Lee K. H., et al. , “Managing the CT data explosion: initial experience of archiving volumetric datasets in a mini-PACS,” Proc. SPIE 5748, 427 (2005). 10.1117/12.593549 [DOI] [PMC free article] [PubMed] [Google Scholar]
485.Lou H., Hao W., Cornelius C., “Automatic hanging protocol for chest radiographs,” Proc. SPIE 5748, 33 (2005). 10.1117/12.595419 [DOI] [PubMed] [Google Scholar]
486.Kurup P. K., et al. , “Automatic classification of computed tomography slices into anatomic regions,” Proc. SPIE 5748, 43 (2005). 10.1117/12.595399 [DOI] [Google Scholar]
487.Mun S. K., Cleary K., “The operating room of the future: review of OR 2020 workshop,” Proc. SPIE 5748, 73 (2005). 10.1117/12.604719 [DOI] [Google Scholar]
488.Lemke H. U., Ratib O. M., Horii S. C., “Workflow in the operating room: review of Arrowhead 2004 seminar on imaging and informatics,” Proc. SPIE 5748, 83 (2005). 10.1117/12.606113 [DOI] [Google Scholar]
489.Siddiqui K. M., et al. , “Correlation of radiologists’ image quality perception with quantitative assessment parameters: just-noticeable difference versus peak signal-to-noise ratios,” Proc. SPIE 5748, 58 (2005). 10.1117/12.596140 [DOI] [Google Scholar]
490.Ogden K. M., et al. , “Quantifying the effect of monitor display settings on observer performance,” Proc. SPIE 5748, 455 (2005). 10.1117/12.594626 [DOI] [Google Scholar]
491.Siegel E. L., et al. , “Compression of multi-slice CT: 2D versus 3D JPEG2000 and effects of slice thickness,” Proc. SPIE 5748, 162 (2005). 10.1117/12.596037 [DOI] [Google Scholar]
492.Siddiqui K. M., et al. , “Discrete cosine transform JPEG compression versus 2D JPEG2000 compression: INDmetrix visual discrimination model image quality analysis,” Proc. SPIE 5748, 202 (2005). 10.1117/12.596146 [DOI] [Google Scholar]
493.Rosset A., Ratib A. M., “New GRID-computing platforms for high performance multi-dimensional and multi-modality image rendering,” Proc. SPIE 5748, 218 (2005). 10.1117/12.594221 [DOI] [Google Scholar]
494.Reddy Mogatala H. V., Gallet J., “Secure thin client architecture for DICOM image analysis,” Proc. SPIE 5748, 357 (2005). 10.1117/12.595985 [DOI] [Google Scholar]
495.Chen X., et al. , “Evaluation of security algorithms used for security processing on DICOM images,” Proc. SPIE 5748, 539 (2005). 10.1117/12.596525 [DOI] [Google Scholar]
496.Chawla A. S., Samei E., “A method for reduction of eye fatigue by optimizing the ambient light conditions in radiology reading rooms,” Proc. SPIE 6145, 614503 (2006). 10.1117/12.655688 [DOI] [Google Scholar]
497.Joshi R. L., “On-demand rendering of an oblique slice through 3D volumetric data using KPEG2000 client-server framework,” Proc. SPIE 6145, 614508 (2006). 10.1117/12.653523 [DOI] [Google Scholar]
498.Ratib O., et al. , “Hierarchical storage of large volume of multidetector CT data using distributed servers,” Proc. SPIE 6145, 61450W (2006). 10.1117/12.654616 [DOI] [Google Scholar]
499.Horii S. C., et al. , “Impact of volumetric ultrasound on PACS,” Proc. SPIE 6145, 614512 (2006). 10.1117/12.657135 [DOI] [Google Scholar]
500.Lehmann T. M., Abel J., Weiss C., “The impact of lossless image compression to radiographs,” Proc. SPIE 6145, 614516 (2006). 10.1117/12.651697 [DOI] [Google Scholar]
501.Siddoway D., et al. , “Workflow in interventional radiology: nerve blocks and facet blocks,” Proc. SPIE 6145, 61450B (2006). 10.1117/12.654482 [DOI] [Google Scholar]
502.Guo B., et al. , “An ultrasound image-guided surgical workflow model,” Proc. SPIE 6145, 61450C (2006). 10.1117/12.653558 [DOI] [Google Scholar]
503.Neumuth T., et al. , “Structured recording of intraoperative surgical workflows,” Proc. SPIE 6145, 61450A (2006). 10.1117/12.653462 [DOI] [Google Scholar]
504.Riesmeier J., et al. , “A unified approach for the adequate visualization of structured reports,” Proc. SPIE 6145, 61450P (2006). 10.1117/12.653396 [DOI] [Google Scholar]
505.Liu B. J., et al. , “A DICOM-RT based ePR radiation therapy information system for decision-support of brain tumor patients,” Proc. SPIE 6145, 61450S (2006). 10.1117/12.653671 [DOI] [Google Scholar]
506.Noumeir R., “IHE cross-enterprise document sharing for imaging: design challenges,” Proc. SPIE 6145, 61450Q (2006). 10.1117/12.653433 [DOI] [Google Scholar]
507.Kim J. I., et al. , “Applying XDS for sharing CDA-based medical records,” Proc. SPIE 6145, 614518 (2006). 10.1117/12.652037 [DOI] [Google Scholar]
508.dos Santos M., Furuie S. S., “Sharing medical images: a proposal of a reference image database,” Proc. SPIE 6145, 61451D (2006). 10.1117/12.653106 [DOI] [Google Scholar]
509.Nocco U., et al. , “Video and LAN solutions for a digital OR: the Varese experience,” Proc. SPIE 6516, 651605 (2007). 10.1117/12.708788 [DOI] [Google Scholar]
510.Lemke H. U., Berliner L., “Specification and design of a therapy imaging and model management system (TIMMS),” Proc. SPIE 6516, 651602 (2007). 10.1117/12.719530 [DOI] [Google Scholar]
511.Lemke H. U., “Summary of the white paper of DICOM WG24 ‘DICOM in surgery’,” Proc. SPIE 6516, 651603 (2007). 10.1117/12.719536 [DOI] [Google Scholar]
512.Zhang J., et al. , “A grid-based implementation of XDS-I as a part of a metropolitan EHR in Shanghai,” Proc. SPIE 6516, 65160R (2007). 10.1117/12.709117 [DOI] [Google Scholar]
513.Horii S. C., “Whole-slide imaging in pathology: the potential impact on PACS,” Proc. SPIE 6516, 65160B (2007). 10.1117/12.719564 [DOI] [Google Scholar]
514.Caban J. J., Wood B. J., Park A., “Flexible high-resolution display systems for the next generation of radiology reading rooms,” Proc. SPIE 6516, 651607 (2007). 10.1117/12.710305 [DOI] [Google Scholar]
515.Fan J., Roehrig H., Krupinski E., “Characterization of color-related properties of displays for medical applications,” Proc. SPIE 6516, 65160X (2007). 10.1117/12.709077 [DOI] [Google Scholar]
516.Roehrig H., et al. , “Image quality evaluation of color displays using a fovean color camera,” Proc. SPIE 6516, 651611 (2007). 10.1117/12.713865 [DOI] [Google Scholar]
517.Saha A., Liang H., Badano A., “Characterization of mobile display systems for use in medical imaging,” Proc. SPIE 6516, 651610 (2007). 10.1117/12.709002 [DOI] [Google Scholar]
518.Chawla A. S., et al. , “Effect of increased ambient lighting on detectability: a psychophysical study,” Proc. SPIE 6516, 651617 (2007). 10.1117/12.713559 [DOI] [Google Scholar]
519.Juluru K., et al. , “Volumetric measurements of pulmonary nodules: variability in automated analysis tools,” Proc. SPIE 6516, 651613 (2007). 10.1117/12.711642 [DOI] [Google Scholar]
520.Zhou Z., et al. , “PACS-CAD toolkit for integrating an independent CAD workstation to diagnostic workflow,” Proc. SPIE 6516, 651609 (2007). 10.1117/12.710128 [DOI] [Google Scholar]
521.Deserno T. A., Antani S., Long R., “Gaps in content-based image retrieval,” Proc. SPIE 6516, 65160J (2007). 10.1117/12.709912 [DOI] [PMC free article] [PubMed] [Google Scholar]
522.Lee J., et al. , “Design and implementation of a fault-tolerant and dynamic metadata database for clinical trials,” Proc. SPIE 6516, 65160O (2007). 10.1117/12.710550 [DOI] [Google Scholar]
523.Suzuki H., et al. , “Anonymization server system for DICOM images,” Proc. SPIE 6516, 65160Z (2007). 10.1117/12.709947 [DOI] [Google Scholar]
524.Schrader T., et al. , “Virtual microscopy in medical research: Open European Nephrology Science Center (OpEN.SC),” Proc. SPIE 6516, 651606 (2007). 10.1117/12.709623 [DOI] [Google Scholar]
525.Chen J. J., et al. , “Observer success rates for identification of 3D surface reconstructed facial images and implications for patient privacy and security,” Proc. SPIE 6516, 65161B (2007). 10.1117/12.717850 [DOI] [PMC free article] [PubMed] [Google Scholar]
526.Andriole K. P., Siddiqui K. M., “Front matter: Volume 6919,” Proc. SPIE 6919, 691901 (2008). 10.1117/12.798406 [DOI] [Google Scholar]
527.Le A., et al. , “The design and implementation of decision support tools of proton beam therapy treatment planning of brain cancer patients,” Proc. SPIE 6919, 69190G (2008). 10.1117/12.770791 [DOI] [Google Scholar]
528.Zhang A., et al. , “Web-based computer-aided-diagnosis (CAD) system for bone age assessment (BAA) of children,” Proc. SPIE 6919, 69190H (2008). 10.1117/12.770785 [DOI] [Google Scholar]
529.Safdar N., et al. , “Role of computer aided detection (CAD) integration: case study with meniscal and articular cartilage CAD applications,” Proc. SPIE 6919, 69190J (2008). 10.1117/12.779304 [DOI] [Google Scholar]
530.Gutierrex M. A., et al. , “Development of a mobile HIS/PACS workstation to assist critical cardiac patients in an intensive care unit,” Proc. SPIE 6919, 691915 (2008). 10.1117/12.770565 [DOI] [Google Scholar]
531.Mayoral R., Vazquez A., Burgert O., “A general framework for data steaming in the digital operating room,” Proc. SPIE 6919, 69190W (2008). 10.1117/12.769485 [DOI] [Google Scholar]
532.Stanek S. R., et al. , “Automatic real-time capture and segmentation of endoscopy video,” Proc. SPIE 6919, 69190X (2008). 10.1117/12.770930 [DOI] [Google Scholar]
533.Solberg O. V., et al. , “Integration of a real-time video grabber component with the open source image-guided surgery toolkit (IGSTK),” Proc. SPIE 6919, 69190Z (2008). 10.1117/12.772491 [DOI] [Google Scholar]
534.Carlsson G., et al. , “How HL7 version 3 is used at Sahlgrenska University Hospital to exchange information with a central archive,” Proc. SPIE 6919, 691902 (2008). 10.1117/12.770003 [DOI] [Google Scholar]
535.Liao W., Deserno T. M., Spitzer K., “Evaluation of free non-diagnostic DICOM software tools,” Proc. SPIE 6919, 691903 (2008). 10.1117/12.770431 [DOI] [Google Scholar]
536.Lee J., Le A., Liu B., “Integrating DICOM structure reporting (SR) into the medical imaging informatics data grid,” Proc. SPIE 6919, 691904 (2008). 10.1117/12.772742 [DOI] [Google Scholar]
537.Kimpe T., Marchessoux C., “Improved display calibration algorithm for wide viewing angle DICOM GSDF compliance,” Proc. SPIE 6919, 69190P (2008). 10.1117/12.768676 [DOI] [Google Scholar]
538.Xu A., et al. , “Display methods for adjustable grayscale and luminance depth,” Proc. SPIE 6919, 69190Q (2008). 10.1117/12.771675 [DOI] [Google Scholar]
539.Pollard B. J., et al. , “The effect of increased ambient lighting on detection accuracy in uniform and anatomical backgrounds,” Proc. SPIE 6919, 69190R (2008). 10.1117/12.772932 [DOI] [Google Scholar]
540.Lee J. C., Ma K. C., Liu B. J., “Assuring image authenticity within a data grid using lossless digital signature embedding and a HIPAA-compliant auditing system,” Proc. SPIE 6919, 69190O (2008). 10.1117/12.772500 [DOI] [Google Scholar]
541.Tsao S., et al. , “RadSearch: A RIS/PACS integrated query tool,” Proc. SPIE 6919, 691909 (2008). 10.1117/12.772983 [DOI] [Google Scholar]
542.Datteri R., Raicu D., Furst J., “Local versus global texture analysis for lung nodule image retrieval,” Proc. SPIE 6919, 691908 (2008). 10.1117/12.770979 [DOI] [Google Scholar]
543.Muhammad M. N., et al. , “Texture versus shape analysis for lung nodule similarity in computed tomography studies,” Proc. SPIE 6919, 69190I (2008). 10.1117/12.771009 [DOI] [Google Scholar]
544.Documet J. R., et al. , “An image-intensive ePR for image-guided minimally invasive spine surgery applications including real-time intra-operative image acquisition, archival and display,” Proc. SPIE 7264, 72640E (2009). 10.1117/12.813610 [DOI] [Google Scholar]
545.Cheng Y., Liu X., Li H., “A robust real-time abnormal region detection framework from capsule endoscopy images,” Proc. SPIE 7264, 72640I (2009). 10.1117/12.813363 [DOI] [Google Scholar]
546.Moin P., et al. , “The development of an MRI lesion quantifying system for multiple sclerosis patients undergoing treatment,” Proc. SPIE 7264, 72640J (2009). 10.1117/12.811947 [DOI] [Google Scholar]
547.Elter M., et al. , “A multi-image approach to CADx of breast cancer with integration into PACS,” Proc. SPIE 7264, 72640X (2009). 10.1117/12.810983 [DOI] [Google Scholar]
548.Lee J. K., et al. , “Evaluation of a computer-aided-detection algorithm for timely diagnosis of small acute intracranial hemorrhage on computed tomography in critical care environment,” Proc. SPIE 7264, 726416 (2009). 10.1117/12.815390 [DOI] [Google Scholar]
549.Maani R., Camorlinga S., Eskicioglu R., “A remote real-time PACS-based platform for medical imaging telemedicine,” Proc. SPIE 7264, 72640Q (2009). 10.1117/12.811621 [DOI] [Google Scholar]
550.Zhang K., et al. , “Design of an image-enabled electronic healthcare record system for regional collaborative healthcare applications,” Proc. SPIE 7264, 72640W (2009). 10.1117/12.810900 [DOI] [Google Scholar]
551.Wang F., Hussels P., Liu P., “Securely and flexibly sharing a biomedical data management system,” Proc. SPIE 7264, 726402 (2009). 10.1117/12.811716 [DOI] [PMC free article] [PubMed] [Google Scholar]
552.Chen J. J., Saenz N. J., Siegel E. L., “The creation of a public database of precision phantoms to facilitate the evaluation and standardization of advanced visualization and quantification software,” Proc. SPIE 7264, 726403 (2009). 10.1117/12.814643 [DOI] [Google Scholar]
553.Welter P., et al. , “Integration of CBIR in radiological routing in accordance with IHE,” Proc. SPIE 7264, 726404 (2009). 10.1117/12.812100 [DOI] [Google Scholar]
554.He Z., et al. , “Combining text retrieval and content-based image retrieval for searching large-scale medical image database in an integrated RIS/PACS environment,” Proc. SPIE 7264, 72640U (2009). 10.1117/12.810671 [DOI] [Google Scholar]
555.Lindskold L., Wintell M., Lundberg N., “Interoperability in healthcare: major challenges in the creation of the enterprise environment,” Proc. SPIE 7264, 72640C (2009). 10.1117/12.811493 [DOI] [Google Scholar]
556.Jomier J., et al. , “A digital archiving system and distributed server-side processing of large datasets,” Proc. SPIE 7264, 726413 (2009). 10.1117/12.812227 [DOI] [Google Scholar]
557.Blodgett K., et al. , “Image storage in radiation oncology: what did we learn from diagnostic radiology?” Proc. SPIE 7264, 726414 (2009). 10.1117/12.813542 [DOI] [Google Scholar]
558.Han W., et al. , “Clinical image processing engine,” Proc. SPIE 7264, 726408 (2009). 10.1117/12.811642 [DOI] [Google Scholar]
559.Zhu Y., et al. , “An automated system to detect and extract texts in medical images for de-identification,” Proc. SPIE 7628, 762803 (2010). 10.1117/12.855588 [DOI] [Google Scholar]
560.Welter P., et al. , “Exemplary design of a DICOM structured report template for CBIR integration into radiological routine,” Proc. SPIE 7628, 76280B (2010). 10.1117/12.844170 [DOI] [Google Scholar]
561.Maani R., et al. , “A practical fast method for medical imaging transmission based on the DICOM protocol,” Proc. SPIE 7628, 76280M (2010). 10.1117/12.843896 [DOI] [Google Scholar]
562.Kim W., Boonn W., “Evaluation of an open source tool for indexing and searching enterprise radiology and pathology reports,” Proc. SPIE 7628, 762806 (2010). 10.1117/12.846772 [DOI] [Google Scholar]
563.Seifert S., et al. , “Semantic annotation of medical image,” Proc. SPIE 7628, 762808 (2010). 10.1117/12.844207 [DOI] [Google Scholar]
564.Park Y. W., et al. , “A zero-footprint 3D visualization system utilizing mobile display technology for timely evaluation of stroke,” Proc. SPIE 7628, 76280U (2010). 10.1117/12.845578 [DOI] [Google Scholar]
565.Honeyman-Buck J., “Transforming the radiological interpretation process: TRIP – where are we now?” Proc. SPIE 7628, 76280R (2010). 10.1117/12.845452 [DOI] [Google Scholar]
566.Cook T. S., et al. , “Analyzing how radiologists recommend follow-up: toward development of an automated tracking and feedback system for clinical, laboratory and radiologic studies,” Proc. SPIE 7628, 76280S (2010). 10.1117/12.845971 [DOI] [Google Scholar]
567.Le A. H., et al. , “Performance evaluation for volumetric segmentation of multiple sclerosis lesions using MATLAB and computing engine in the graphical processing unit (GPU),” Proc. SPIE 7628, 76280W (2010). 10.1117/12.844811 [DOI] [Google Scholar]
568.Kandula P., et al. , “Automated breast imaging-reporting and data system (BI-RADS) category 3 follow-up application: improving patient care and compliance,” Proc. SPIE 7967, 79670B (2011). 10.1117/12.880467 [DOI] [Google Scholar]
569.Morioka C., et al. , “DICOM structured report to track patient’s radiation dose to organs from abdominal CT exam,” Proc. SPIE 7967, 79670X (2011). 10.1117/12.878277 [DOI] [Google Scholar]
570.Zopf J., et al. , “Development of automated detection of radiology reports citing adrenal findings,” Proc. SPIE 7967, 79670A (2011). 10.1117/12.881252 [DOI] [PMC free article] [PubMed] [Google Scholar]
571.Horii S. C., et al. , “Utility of rapid database search for quality assurance: ‘detective work’ in uncovering radiology coding and billing errors,” Proc. SPIE 7967, 796705 (2011). 10.1117/12.878816 [DOI] [Google Scholar]
572.Liu B., et al. , “A multimedia electronic patient record (ePR) system to improve decision support in pre-and rehabilitation through clinical and movement analysis,” Proc. SPIE 7967, 79670J (2011). 10.1117/12.878270 [DOI] [Google Scholar]
573.Moulik S., Boonn W., “The role of GPU computing in medical image analysis and visualization,” Proc. SPIE 7967, 79670L (2011). 10.1117/12.880093 [DOI] [Google Scholar]
574.Tan B., et al. , “Design and evaluation of web-based image transmission and display with different protocols,” Proc. SPIE 7967, 79670S (2011). 10.1117/12.877755 [DOI] [Google Scholar]
575.Burgert O., Liebmann P., Treichel T., “IHE for surgery: scope and first proposals for a new domain within the integrating the healthcare enterprise initiative,” Proc. SPIE 7967, 79670P (2011). 10.1117/12.877812 [DOI] [Google Scholar]
576.Reza J., et al. , “2D and 3D mammography observer study,” Proc. SPIE 7967, 79670N (2011). 10.1117/12.878570 [DOI] [Google Scholar]
577.Maeder A. J., Planitz B. M., El Rifai D., “A cloud-based medical image repository,” Proc. SPIE 8319, 831908 (2012). 10.1117/12.912296 [DOI] [Google Scholar]
578.De Paepe L., et al. , “Performance evaluation of a visual display calibration algorithm for iPad,” Proc. SPIE 8319, 831909 (2012). 10.1117/12.911265 [DOI] [Google Scholar]
579.Pathak S. D., et al. , “Linking DICOM pixel data with radiology reports using automatic semantic annotation,” Proc. SPIE 8319, 83190D (2012). 10.1117/12.912391 [DOI] [Google Scholar]
580.Lu H., et al. , “Medical image retrieval system using multiple features from 3D ROIs,” Proc. SPIE 8319, 83190E (2012). 10.1117/12.911806 [DOI] [Google Scholar]
581.Deshpande R. R., et al. , “Data MINING DICOM RT objects for quality control in radiation oncology,” Proc. SPIE 8319, 83190Q (2012). 10.1117/12.911075 [DOI] [Google Scholar]
582.Wang X., Martel A., “Creating a semantic lesion database for computer-aided MR mammography,” Proc. SPIE 8319, 83190X (2012). 10.1117/12.911299 [DOI] [Google Scholar]
583.Wang X., et al. , “A computer-aided detection (CAD) system with a 3D algorithm for small acute intracranial hemorrhage,” Proc. SPIE 8319, 831913 (2012). 10.1117/12.910958 [DOI] [Google Scholar]
584.Wu S., Avgeropoulos N. G., Rippe D. J., “Computer-assisted identification and volumetric quantification of dynamic contrast enhancement in brain MRI: an interactive system,” Proc. SPIE 8674, 867407 (2013). 10.1117/12.2008163 [DOI] [Google Scholar]
585.Satoh H., et al. , “Teleradiology network system on cloud using the web medical image conference system with a new information security solution,” Proc. SPIE 8674, 86740X (2013). 10.1117/12.2006983 [DOI] [Google Scholar]
586.Ismail M., Ning Y., Philbin J., “Transmission of DICOM studies using multi-series DICOM format,” Proc. SPIE 8674, 86740E (2013). 10.1117/12.2007590 [DOI] [Google Scholar]
587.Huang J., et al. , “Integration of PACS and CAD systems using DICOMDIR and open-source tools,” Proc. SPIE 8674, 86740V (2013). 10.1117/12.2001560 [DOI] [Google Scholar]
588.Wahle A., et al. , “Extending the XNAT archive tool for image and analysis management in ophthalmology research,” Proc. SPIE 8674, 86740M (2013). 10.1117/12.2007966 [DOI] [Google Scholar]
589.dos Santos M., Fujino A., “Developing an interactive and MIRC-compliant radiology teaching file system,” Proc. SPIE 8674, 86740U (2013). 10.1117/12.2008135 [DOI] [PubMed] [Google Scholar]
590.Lemke H. U., Berliner L., “The digital operating room: towards intelligent infrastructures and processes,” Proc. SPIE 8674, 86740R (2013). 10.1117/12.2013697 [DOI] [Google Scholar]
591.Gutenko I., et al. , “Remote volume rendering pipeline for mHealth applications,” Proc. SPIE 9039, 903904 (2014). 10.1117/12.2043946 [DOI] [Google Scholar]
592.Haak D., et al. , “OC ToGo: bed site image integration in to openclinica with mobile devices,” Proc. SPIE 9039, 903909 (2014). 10.1117/12.2042847 [DOI] [Google Scholar]
593.Zhang J., et al. , “Medical imaging document sharing solutions for various kinds of healthcare services based on IHE XDS/XDS-I profiles,” Proc. SPIE 9039, 90390B (2014). 10.1117/12.2042970 [DOI] [Google Scholar]
594.Patel M. N., et al. , “Automated collection of medical images for research from heterogeneous systems: trials and tribulations,” Proc. SPIE 9039, 90390C (2014). 10.1117/12.2043656 [DOI] [Google Scholar]
595.Deshpande R., et al. , “A collaborative framework for contributing DICOM RT PHI (protected health information) to augment data mining in clinical decision support,” Proc. SPIE 9039, 90390K (2014). 10.1117/12.2044010 [DOI] [Google Scholar]
596.Kahn C. E., Jr, “Incorporating intelligence into structured radiology reports,” Proc. SPIE 9039, 90390M (2014). 10.1117/12.2043912 [DOI] [Google Scholar]
597.Zhang J., “Big data issues in medical imaging informatics,” Proc. SPIE 9418, 941803 (2015). 10.1117/12.2081336 [DOI] [Google Scholar]
598.Lindskold L., Alvfeldt G., Wintell M., “What makes ‘big data’ different from ‘regular data’ within radiology? The easiest answer: when it no longer fits into Excel!” Proc. SPIE 9418, 941805 (2015). 10.1117/12.2081359 [DOI] [Google Scholar]
599.Bougatf N., Bendl R., Debus J., “Towards secondary use of heterogeneous radio-oncologic data for retrospective clinical trials: service-oriented connection of a central research database with image analysis tools,” Proc. SPIE 9418, 941807 (2015). 10.1117/12.2084365 [DOI] [Google Scholar]
600.Ma K., et al. , “Big data in multiple sclerosis: development of a web-based longitudinal study viewer in an imaging informatics-based e folder system for complex data analysis and management,” Proc. SPIE 9418, 941809 (2015). 10.1117/12.2082650 [DOI] [Google Scholar]
601.Tittner L., et al. , “Web-based platform for collaborative medical imaging research,” Proc. SPIE 9418, 94180B (2015). 10.1117/12.2081697 [DOI] [Google Scholar]
602.Parikh A., Mehta N., “PACS: next generation,” Proc. SPIE 9418, 94180G (2015). 10.1117/12.2081987 [DOI] [Google Scholar]
603.Al-Hajeri M., Clarke M., “Future trends in picture archiving and communication system (PACS),” Proc. SPIE 9418, 94180K (2015). 10.1117/12.2179373 [DOI] [PubMed] [Google Scholar]
604.Xia W., Gao X., “The standardization of super resolution optical microscopic images based on DICOM,” Proc. SPIE 9418, 94180Z (2015). 10.1117/12.2081009 [DOI] [Google Scholar]
605.Chang C. K., et al. , “Web-based 3D digital pathology framework for large-mapping data scanned by FF-OCT,” Proc. SPIE 9418, 94180H (2015). 10.1117/12.2081587 [DOI] [Google Scholar]
606.Patel M. N., et al. , “Quantitative imaging features: extension of the oncology medical image database,” Proc. SPIE 9418, 941812 (2015). 10.1117/12.2082114 [DOI] [Google Scholar]
607.Milovanovic L., et al. , “Investigation into the need for ingesting foreign imaging exams into local systems and evaluation of the design challenges of foreign exam management (FEM),” Proc. SPIE 9418, 94180N (2015). 10.1117/12.2082879 [DOI] [Google Scholar]
608.Weisenthal S., et al. , “Open-source radiation exposure extraction engine (RE3) for dose monitoring,” Proc. SPIE 9418, 941813 (2015). 10.1117/12.2082197 [DOI] [Google Scholar]
609.Wang S., et al. , “Radiogenomic analysis of breast cancer: dynamic contrast enhanced magnetic resonance imaging based features are associated with molecular subtypes,” Proc. SPIE 9789, 978904 (2016). 10.1117/12.2217658 [DOI] [Google Scholar]
610.Ma J., et al. , “Automatic lung nodule classification with radiomics approach,” Proc. SPIE 9789, 978906 (2016). 10.1117/12.2220768 [DOI] [Google Scholar]
611.Izzo R. L., et al. , “3D printed cardiac phantom for procedural planning of a transcatheter native mitral valve replacement,” Proc. SPIE 9789, 978908 (2016). 10.1117/12.2216952 [DOI] [PMC free article] [PubMed] [Google Scholar]
612.Haak D., et al. , “Interconnecting smartphone, image analysis server and case report forms in clinical trials for automatic skin lesion tracking in clinical trials,” Proc. SPIE 9789, 97890B (2016). 10.1117/12.2216657 [DOI] [Google Scholar]
613.Chen P. H., et al. , “Feasibility of streamlining an interactive Bayesian-based diagnostic support tool designed for clinical practice,” Proc. SPIE 9789, 97890C (2016). 10.1117/12.2216574 [DOI] [Google Scholar]
614.Deshpande R., et al. , “Multisite evaluation of a clinical decision support system for radiation therapy,” Proc. SPIE 9789, 97890C (2016). 10.1117/12.2216574 [DOI] [Google Scholar]
615.Bao S., et al. , “Performance management of high performance computing for medical image processing in Amazon Web Services,” Proc. SPIE 9789, 97890Q (2016). 10.1117/12.2217396 [DOI] [PMC free article] [PubMed] [Google Scholar]
616.Xue Z., et al. , “Improving face image extraction by using deep learning technique,” Proc. SPIE 9789, 97890J (2016). 10.1117/12.2216278 [DOI] [Google Scholar]
617.Zi D., et al. , “Mass classification in mammography with multi-agent based fusion of human and machine intelligence,” Proc. SPIE 9789, 97890R (2016). 10.1117/12.2225139 [DOI] [Google Scholar]
618.Wang Z., et al. , “Development of a web-based informatics system utilizing quantitative imaging features for predicting outcomes in stroke rehabilitation clinical trials,” Proc. SPIE 9789, 97890Y (2016). 10.1117/12.2218093 [DOI] [Google Scholar]
619.Aghaei F., et al. , “Implementation of a computer-aided detection tool for quantification of intracranial radiologic markers on brain CT images,” Proc. SPIE 10138, 1013805 (2017). 10.1117/12.2254094 [DOI] [Google Scholar]
620.Li J., et al. , “Discriminating between benign and malignant breast tumors using 3D convolutional neural network in dynamic contrast enhanced MR images,” Proc. SPIE 10138, 1013808 (2017). 10.1117/12.2254716 [DOI] [Google Scholar]
621.Kim E., et al. , “Digital pathology annotation data for improved deep neural network classification,” Proc. SPIE 10138, 101380D (2017). 10.1117/12.2254491 [DOI] [Google Scholar]
622.Ding M., et al. , “Local-global classifier fusion for screening chest radiographs,” Proc. SPIE 10138, 101380A (2017). 10.1117/12.2252459 [DOI] [Google Scholar]
623.Sims D. I., Siadat M. R., “Frequency-based similarity detection of structures in human brain,” Proc. SPIE 10138, 1013804 (2017). 10.1117/12.2247085 [DOI] [Google Scholar]
624.Hong A. L., et al. , “Feasibility of fabricating personalized 3D-printed bone grafts guided by high-resolution imaging,” Proc. SPIE 10138, 101380O (2017). 10.1117/12.2254475 [DOI] [Google Scholar]
625.Meess K. M., et al. , “3D printed abdominal aortic aneurysm phantom for image guided surgical planning with a patient specific fenestrated endovascular graft system,” Proc. SPIE 10138, 101380P (2017). 10.1117/12.2253902 [DOI] [PMC free article] [PubMed] [Google Scholar]
626.Verma S., et al. , “The development of a decision support system with an interactive clinical user interface for estimating treatment parameters in radiation therapy in order to reduce radiation dose in head and neck patients,” Proc. SPIE 10138, 101380M (2017). 10.1117/12.2257029 [DOI] [Google Scholar]
627.Sirazitdinova E., Deserno T. M., “System design for 3D wound imaging using low-cost mobile devices,” Proc. SPIE 10138, 1013810 (2017). 10.1117/12.2254389 [DOI] [PubMed] [Google Scholar]
628.Cao X., Xu X., Voss S., “DICOM image quantification secondary capture (DICOM IQSC) integrated with numeric results, regions and curves: implementation and applications in nuclear medicine,” Proc. SPIE 10138, 1013814 (2017). 10.1117/12.2254137 [DOI] [Google Scholar]
629.Erickson B. J., Siegel E. L., “Will computers replace radiologists for primary reads in 20 years: a debate,” Proc. SPIE 10579, 1057902 (2018). 10.1117/12.2300386 [DOI] [Google Scholar]
630.Bernie Huang H. K., “PACS-based multimedia imaging informatics: 3rd edition,” Proc. SPIE 10579, 1057903 (2018). 10.1117/12.2295769 [DOI] [Google Scholar]
631.Ren J., et al. , “Differentiation among prostate cancer patients with gleason score of 7 using histopathology whole-slide image and genomic data,” Proc. SPIE 10579, 1057904 (2018). 10.1117/12.2293193 [DOI] [PMC free article] [PubMed] [Google Scholar]
632.Park J. H., et al. , “Crowd-assisted polyp annotation of virtual colonoscopy videos,” Proc. SPIE 10579, 105790M (2018). 10.1117/12.2292899 [DOI] [Google Scholar]
633.Heidari M., et al. , “Applying a machine learning model using a locally preserving projection based feature regeneration algorithm to predict breast cancer risk,” Proc. SPIE 10579, 105790T (2018). 10.1117/12.2291524 [DOI] [Google Scholar]
634.Xue Z., et al. , “Localizing tuberculosis in chest radiographs with deep learning,” Proc. SPIE 10579, 105790U (2018). 10.1117/12.2293022 [DOI] [Google Scholar]
635.Leighs J. A., Halling-Brown M. D., Patel M. N., “Mining hidden data to predict patient prognosis: texture feature extraction and machine learning in mammography,” Proc. SPIE 10579, 105790W (2018). 10.1117/12.2293523 [DOI] [Google Scholar]
636.Sahu P., Yu D., Qin H., “Apply lightweight deep learning on internet of things for low-cost and easy-to-access skin cancer detection,” Proc. SPIE 10579, 1057912 (2018). 10.1117/12.2293350 [DOI] [Google Scholar]
637.Zhang S., et al. , “The application of deep learning for diabetic retinopathy prescreening in research eye-PACS,” Proc. SPIE 10579, 1057913 (2018). 10.1117/12.2296673 [DOI] [Google Scholar]
638.Ni Y., et al. , “Preliminary study of benign and malignant differentiation of small pulmonary nodules in lung CT images by deep learning convolutional neural network,” Proc. SPIE 10579, 1057916 (2018). 10.1117/12.2294483 [DOI] [Google Scholar]
639.Kamezawa H., Arimura H., Soufi M., “Survival prediction of squamous cell head and neck cancer patients based on radiomic features selected from lung cancer patients using artificial neural network,” Proc. SPIE 10579, 1057918 (2018). 10.1117/12.2293415 [DOI] [Google Scholar]
640.Lee D. Z., et al. , “Rapid 3D bioprinting from medical images: an application to bone scaffolding,” Proc. SPIE 10579, 105790H (2018). 10.1117/12.2293606 [DOI] [Google Scholar]
641.Crosby J., et al. , “Impact of imprinted labels on deep learning classification of AP and PA thoracic radiographs,” Proc. SPIE 10954, 109540E (2019). 10.1117/12.2513026 [DOI] [Google Scholar]
642.Zhang L., et al. , “Deep-learning method for tumor segmentation in breast DCE-MRI,” Proc. SPIE 10954, 109540F (2019). 10.1117/12.2513090 [DOI] [Google Scholar]
643.Kim J., et al. , “Optic disc segmentation in fundus images using deep learning,” Proc. SPIE 10954, 109540H (2019). 10.1117/12.2512798 [DOI] [Google Scholar]
644.Khened M., et al. , “3D convolutional neural networks for molecular subtype prediction in glioblastoma multiforme,” Proc. SPIE 10954, 1095413 (2019). 10.1117/12.2512417 [DOI] [Google Scholar]
645.Dutta S., Das B., Kaushik S., “Assessment of optimal deep learning configuration for vertebrae segmentation from CT images,” Proc. SPIE 10954, 109541A (2019). 10.1117/12.2512636 [DOI] [Google Scholar]
646.Tachibana R., et al. , “Electronic cleansing in CT colonography using a generative adversarial network,” Proc. SPIE 10954, 1095419 (2019). 10.1117/12.2512466 [DOI] [Google Scholar]
647.Guan S., Loew M., “Using generative adversarial networks and transfer learning for breast cancer detection by convolutional neural networks,” Proc. SPIE 10954, 109541C (2019). 10.1117/12.2512671 [DOI] [PMC free article] [PubMed] [Google Scholar]
648.Zhu H., Paschalidis I. C., Tahmasebi A. M., “Context-based bidirectional LSTM model for sequence labeling in clinical reports,” Proc. SPIE 10954, 109540J (2019). 10.1117/12.2512103 [DOI] [Google Scholar]
649.Kolli K. K., et al. , “Improved functional assessment of ischemic severity using 3D printed models,” Proc. SPIE 10954, 109540B (2019). 10.1117/12.2512779 [DOI] [PMC free article] [PubMed] [Google Scholar]
650.Baumann K., et al. , “3D Printable lung substitutes for particle therapy on the base of high-resolution CTs for mimicking Bragg peak degradation,” Proc. SPIE 10954, 1095414 (2019). 10.1117/12.2512742 [DOI] [Google Scholar]
651.Lee D. I., Yang Z., Kim J. H., “A 3D printing-based realistic anthropomorphic dental phantom and it imaging evaluation,” Proc. SPIE 10954, 1095415 (2019). 10.1117/12.2513155 [DOI] [Google Scholar]
652.Yang Y., et al. , “Design and implementation of a new generation of PACS based on artificial intelligent visualization,” Proc. SPIE 11318, 113180S (2020). 10.1117/12.2548921 [DOI] [Google Scholar]
653.Murao K., et al. , “Cloud platform for deep learning-based CAD via collaboration between Japanese medical societies and institutes of informatics,” Proc. SPIE 11318, 113180T (2020). 10.1117/12.2543521 [DOI] [Google Scholar]
654.Senko J. L., et al. , “Challenges and limitations of patient specific mitral valve 3D printing,” Proc. SPIE 11318, 1131805 (2020). 10.1117/12.2549140 [DOI] [Google Scholar]
655.Tavakoli M., Jazani S., Nazar M., “Automated detection of microaneurysms in color fundus images using deep learning with different preprocessing approaches,” Proc. SPIE 11318, 113180E (2020). 10.1117/12.2548526 [DOI] [Google Scholar]
656.Narayanan B. N., Davuluru V. S. P., Hardie R. C., “Two-stage deep learning architecture for pneumonia detection and its diagnosis in chest radiographs,” Proc. SPIE 11318, 113180G (2020). 10.1117/12.2547635 [DOI] [Google Scholar]
657.Dutta S., Prakash P., Matthews C. G., “Impact of data augmentation techniques on a deep learning based medical imaging task,” Proc. SPIE 11318, 113180M (2020). 10.1117/12.2549806 [DOI] [Google Scholar]
658.Zheng D., Yang Y., Li W., “A method of dividing clinical data set for medical image AI training,” Proc. SPIE 11318, 113180N (2020). 10.1117/12.2549552 [DOI] [Google Scholar]
659.Zhang L., et al. , “Fully automated tumor localization and segmentation in breast CDE MRI using deep learning and kinetic prior,” Proc. SPIE 11318, 113180Z (2020). 10.1117/12.2551372 [DOI] [Google Scholar]
660.Zou J., et al. , “Deep learning for nuclei segmentation and cell classification in cervical liquid based cytology,” Proc. SPIE 11318, 1131811 (2020). 10.1117/12.2549547 [DOI] [Google Scholar]
661.Lei Y., et al. , “Automated coronary artery segmentation in coronary computed tomography angiography (CCTA) using deep learning neural networks,” Proc. SPIE 11318, 1131812 (2020). 10.1117/12.2550368 [DOI] [Google Scholar]
662.Wan Y., et al. , “Feasibility of predicting pancreatic neuroendocrine tumor grade using deep features from unsupervised learning,” Proc. SPIE 11318, 113180O (2020). 10.1117/12.2548723 [DOI] [Google Scholar]
663.Liu Y., et al. , “CT-based pancreatic multi-organ segmentation by a 3D deep attention U-net network,” Proc. SPIE 11318, 1131813 (2020). 10.1117/12.2550374 [DOI] [Google Scholar]
664.Uemura T., et al. , “GAN-based survival prediction model from CT images of patients with idiopathic pulmonary fibrosis,” Proc. SPIE 11318, 113181F (2020). 10.1117/12.2551369 [DOI] [Google Scholar]
665.Reeves J. J., Longhurst C. A., “Clinical information systems and COVID-19: support for health system response,” Proc. SPIE 11601, 1160104 (2021). 10.1117/12.2586608 [DOI] [Google Scholar]
666.Jadon S., “COVID-19 detection from scarce chest X-ray image data using few-shot deep learning approach,” Proc. SPIE 11601, 116010X (2021). 10.1117/12.2581496 [DOI] [Google Scholar]
667.Uemura T., et al. , “U-radiomics for predicting survival of patients with COVID-19,” Proc. SPIE 11601, 1160110 (2021). 10.1117/12.2581907 [DOI] [Google Scholar]
668.Wang X., Jiang T., Il H. C., “Human epithelial-2 cell image classification using deep unsupervised learning and gradient boosting trees,” Proc. SPIE 11601, 1160105 (2021). 10.1117/12.2582023 [DOI] [Google Scholar]
669.Taufeeque M., et al. , “Multi-camera, multi-person and real-time fall detection using long short term memory,” Proc. SPIE 11601, 1160109 (2021). 10.1117/12.2580700 [DOI] [Google Scholar]
670.Singh H., Saini S. S., Lakshminarayanan V., “Real or fake? Fourier analysis of generative adversarial network fundus images,” Proc. SPIE 11601, 116010H (2021). 10.1117/12.2581078 [DOI] [Google Scholar]
671.Subbanna N., et al. , “Understanding privacy risks in typical deep learning models for medical image analysis,” Proc. SPIE 11601, 116010E (2021). 10.1117/12.2582014 [DOI] [Google Scholar]
672.Gutierrez E., et al. , “Combined thermal and color 3D model for wound evaluation from handheld devices,” Proc. SPIE 11601, 1160108 (2021). 10.1117/12.2580669 [DOI] [Google Scholar]
673.Sommer K. N., et al. , “Evaluation of challenges and limitations of mechanical thrombectomy using 3D printed neurovascular phantoms,” Proc. SPIE 11601, 116010B (2021). 10.1117/12.2580962 [DOI] [PMC free article] [PubMed] [Google Scholar]
674.Olson J., et al. , “Making a difference: an integrated PACS workflow for evaluating longitudinal changes across serial imaging,” Proc. SPIE 11601, 116010O (2021). 10.1117/12.2582209 [DOI] [Google Scholar]
675.Horii S. C., “Reading room design in the COVID-19 era: what have we learned and what can we do better,” Proc. SPIE PC12037, PC1203701 (2022). 10.1117/12.2620421 [DOI] [Google Scholar]
676.Xu W., Huang A., “Multi-camera operating room activity analysis for workflow analysis,” Proc. SPIE 12037, 120370B (2022). 10.1117/12.2611586 [DOI] [Google Scholar]
677.Kopchick B., et al. , “Medical image de-identification using cloud services,” Proc. SPIE 12037, 120370J (2022). 10.1117/12.2608972 [DOI] [Google Scholar]
678.Souza R., et al. , “A comparative analysis of the impact of data distribution on distributed learning with a traveling model for brain age prediction,” Proc. SPIE 12037, 1203702 (2022). 10.1117/12.2612728 [DOI] [Google Scholar]
679.Zhou S., et al. , “Communication-efficient federated learning for multi-institutional medical image classification,” Proc. SPIE 12037, 1203703 (2022). 10.1117/12.2611654 [DOI] [PMC free article] [PubMed] [Google Scholar]
680.Landreth J. L., et al. , “Implementation of convolutional neural networks for respiratory rate detection,” Proc. SPIE 12037, 1203705 (2022). 10.1117/12.2611472 [DOI] [Google Scholar]
681.Nappi J. J., et al. , “Unsupervised 3D prediction model for pulmonary disease progression in chest CT,” Proc. SPIE 12037, 120370O (2022). 10.1117/12.2612375 [DOI] [Google Scholar]
682.Nappi J. J., et al. , “Uncertainty quantification in 3D deep learning for detecting serrated polyps in CT colonography,” Proc. SPIE 12037, 120370T (2022). 10.1117/12.2612637 [DOI] [Google Scholar]
683.Isosalo A., et al. , “Evaluation of different convolutional neural network encoder-decoder architectures for breast mass segmentation,” Proc. SPIE 12037, 120370W (2022). 10.1117/12.2628190 [DOI] [Google Scholar]
684.Chang P. D., “Clinical implementation of deep learning in the radiology workflow: opportunities and challenges,” Proc. SPIE PC12037, PC1203702 (2022). 10.1117/12.2620422 [DOI] [Google Scholar]

[r1] 1.Dwyer S. J., III, et al. , “Cost of managing digital diagnostic images for a 614 bed hospital,” Proc. SPIE 0318, 3 (1982). 10.1117/12.967614 [DOI] [PMC free article] [PubMed] [Google Scholar]

[r2] 2.Dwyer S. J., III, et al. , “Salient characteristics of a distributed diagnostic imaging management system for a radiology department,” Proc. SPIE 0318, 194 (1982). 10.1117/12.967645 [DOI] [Google Scholar]

[r3] 3.Duerickx A. J., Pisa E. J., “Filmless picture archiving and communication in diagnostic radiology,” Proc. SPIE 0318, 9 (1982). 10.1117/12.967615 [DOI] [Google Scholar]

[r4] 4.Vizy K. N., “Digital radiography and picture archiving and communication systems (PACS)”. Proc. SPIE 0318, 348 (1982). 10.1117/12.967674 [DOI] [Google Scholar]

[r5] 5.Staab E. V., et al. , “Medical image communication system: plan, management and initial experience in prototype at the University of North Carolina,” Proc. SPIE 0318, 19 (1982). 10.1117/12.967616 [DOI] [Google Scholar]

[r6] 6.Bohm M., et al. , “Image management in the system CA/1,” Proc. SPIE 0318, 161 (1982). 10.1117/12.967640 [DOI] [Google Scholar]

[r7] 7.Cox J. R., et al. , “Study of a distributed picture archiving and communication system for radiology,” Proc. SPIE 0318, 133 (1982). 10.1117/12.967635 [DOI] [Google Scholar]

[r8] 8.Maguire G. Q., Jr., et al. , “Image processing requirements in hospitals and an integrated systems approach,” Proc. SPIE 0318, 206 (1982). 10.1117/12.967647 [DOI] [Google Scholar]

[r9] 9.Arenson R. L., et al. , “Comprehensive radiology management system without picture archival and communication system (PACS),” Proc. SPIE 0318, 334 (1982). 10.1117/12.967671 [DOI] [Google Scholar]

[r10] 10.Arenson R. L., et al. , “Fiber optic communication system for medical images,” Proc. SPIE 0318, 74 (1982). 10.1117/12.967626 [DOI] [Google Scholar]

[r11] 11.Skinner F. L., et al. , “The teleradiology field demonstration,” Proc. SPIE 0318, 168 (1982). 10.1117/12.967641 [DOI] [Google Scholar]

[r12] 12.Blom G. M., “Optical disc data storage,” Proc. SPIE 0318, 43 (1982). 10.1117/12.967621 [DOI] [Google Scholar]

[r13] 13.Billingsley F. C., “Landsat computer-compatible tape family,” Proc. SPIE 0318, 278 (1982). 10.1117/12.967662 [DOI] [Google Scholar]

[r14] 14.Schneider R. H., “The role of standards in the development of systems for communication and archiving medical images,” Proc. SPIE 0318, 270 (1982). 10.1117/12.967659 [DOI] [Google Scholar]

[r15] 15.Prewitt J. M. S., “IEEE logical format for external exchange of image data bases,” Proc. SPIE 0318, 272 (1982). 10.1117/12.967660 [DOI] [Google Scholar]

[r16] 16.Wake R. H., et al. , “Equipment manufacturers’ view on PACS,” Proc. SPIE 0318, 430 (1982). 10.1117/12.967690 [DOI] [Google Scholar]

[r17] 17.Glenn W., et al. , “The medical community’s view on PACS,” Proc. SPIE 0318, 475 (1982). 10.1117/12.967695 [DOI] [Google Scholar]

[r18] 18.Huang H. K., et al. , “Dual-potential imaging in digital radiography,” Proc. SPIE 0372, 122 (1982). 10.1117/12.934504 [DOI] [Google Scholar]

[r19] 19.Templeton A. W., “Keynote address: concepts of a peripheralized image management system,” Proc. SPIE 0418, 2 (1983). 10.1117/12.935950 [DOI] [Google Scholar]

[r20] 20.Marion J. L., “Analysis of justification for modality integration,” Proc. SPIE 0418, 17 (1983). 10.1117/12.935953 [DOI] [Google Scholar]

[r21] 21.Duerinckx A. J., “PACS status review: 1983,” Proc. SPIE 0418, 68 (1983). 10.1117/12.935961 [DOI] [Google Scholar]

[r22] 22.Cywinski J. K., et al. , “Medical image distribution, storage, and retrieval network: the M/NET,” Proc. SPIE 0418, 74 (1983). 10.1117/12.935962 [DOI] [Google Scholar]

[r23] 23.Blaine G. J., et al. , “PACS workbench at mallinckrodt institute of radiology (MIR),” Proc. SPIE 0418, 80 (1983). 10.1117/12.935963 [DOI] [PMC free article] [PubMed] [Google Scholar]

[r24] 24.Yoshizaki O., et al. , “Total medical imaging system,” Proc. SPIE 0418, 127 (1983). 10.1117/12.935971 [DOI] [Google Scholar]

[r25] 25.Rutherford H. G., Gray M. J., “Digital light box, one of the integral pieces of PACS,” Proc. SPIE 0418, 54 (1983). 10.1117/12.935960 [DOI] [Google Scholar]

[r26] 26.Zeleznik M. P., et al. , “PACS user level requirements,” Proc. SPIE 0418, 172 (1983). 10.1117/12.935978 [DOI] [Google Scholar]

[r27] 27.Huang H. K., et al. , “Design and implementation of multiple digital viewing stations,” Proc. SPIE 0418, 189 (1983). 10.1117/12.935980 [DOI] [Google Scholar]

[r28] 28.Flynn M., et al. , “Requirements for the display and analysis of three-dimensional medical image data,” Proc. SPIE 0418, 213 (1983). 10.1117/12.935984 [DOI] [Google Scholar]

[r29] 29.Anderson W. H., et al. , “Implementation of a diagnostic display and image manipulation node,” Proc. SPIE 0418, 225 (1983). 10.1117/12.935985 [DOI] [Google Scholar]

[r30] 30.Cahill P. T., et al. , “ICDBM: an image communications and data base management system for radiological imaging,” Proc. SPIE 0418, 134 (1983). 10.1117/12.935972 [DOI] [Google Scholar]

[r31] 31.Zeleznik M. P., et al. , “PACS data base design,” Proc. SPIE 0418, 287 (1983). 10.1117/12.935995 [DOI] [Google Scholar]

[r32] 32.Baxter B., et al. , “What types of standards would be useful in PACS activities?” Proc. SPIE 0418, 146 (1983). 10.1117/12.935975 [DOI] [Google Scholar]

[r33] 33.Maguire G. Q., Jr., et al. , “Message protocols for radiologic consultations over a local area network,” Proc. SPIE 0418, 160 (1983). 10.1117/12.935977 [DOI] [Google Scholar]

[r34] 34.Gitlin J. N., et al. , “Professional acceptance of electronic images in radiologic practice,” Proc. SPIE 0418, 258 (1983). 10.1117/12.935991 [DOI] [Google Scholar]

[r35] 35.Arenson R. L., et al. , “Early experience with fiber optic picture archival communication system (PACS),” Proc. SPIE 0418, 116 (1983). 10.1117/12.935969 [DOI] [Google Scholar]

[r36] 36.Horii S., et al. , “Broadband coaxial cable image viewing and processing for radiology,” Proc. SPIE 0418, 247 (1983). 10.1117/12.935990 [DOI] [Google Scholar]

[r37] 37.Drexler J., “Drexon optical storage for digital picture archiving applications,” Proc. SPIE 0418, 30 (1983). 10.1117/12.935955 [DOI] [Google Scholar]

[r38] 38.Wade G. J., “Storing medical images on high density digital tape recorders,” Proc. SPIE 0418, 36 (1983). 10.1117/12.935956 [DOI] [Google Scholar]

[r39] 39.Russell J. T., DeForest R., “Stationary card optical digital storage system,” Proc. SPIE 0418, 42 (1983). 10.1117/12.935957 [DOI] [Google Scholar]

[r40] 40.Dunham J. G., et al. , “Compression for picture archiving and communication in radiology,” Proc. SPIE 0418, 201 (1983). 10.1117/12.935982 [DOI] [Google Scholar]

[r41] 41.Quinn J. F., et al. , “Data compression techniques for CT image archival,” Proc. SPIE 0418, 209 (1983). 10.1117/12.935983 [DOI] [PubMed] [Google Scholar]

[r42] 42.Huang H. K., et al. , “Digital radiology at the University of California, Los Angeles: a feasibility study,” Proc. SPIE 0418, 259 (1983). 10.1117/12.935992 [DOI] [PMC free article] [PubMed] [Google Scholar]

[r43] 43.Herron J. M., et al. , “X-ray imaging with two-dimensional charge-coupled device (CCD) Arrays,” Proc. SPIE 0486, 141 (1984). 10.1117/12.943211 [DOI] [Google Scholar]

[r44] 44.Schwenker R. P., “Film-screen digital radiography,” Proc. SPIE 0486 (1984). 10.1117/12.943212 [DOI] [PubMed] [Google Scholar]

[r45] 45.MacMahon H., et al. , “The effect of pixel size on the detection rate of early pulmonary sarcoidosis in digital chest radiographic systems,” Proc. SPIE 0486, 14 (1984). 10.1117/12.943193 [DOI] [Google Scholar]

[r46] 46.Lisk K. G., “SMPTE test pattern for certification of medical diagnostic display devices,” Proc. SPIE 0486, 79 (1984). 10.1117/12.943201 [DOI] [Google Scholar]

[r47] 47.Lenz R., “Processing and presentation of 3D images,” Proc. SPIE 0515, 298 (1984). 10.1117/12.964776 [DOI] [Google Scholar]

[r48] 48.Graves W. L., et al. , “Modeling and graphic display system for cardiovascular research using random 3-D data,” Proc. SPIE 0515, 304 (1984). 10.1117/12.964777 [DOI] [Google Scholar]

[r49] 49.Chen L. S., et al. , “3D83 – an easy-to-use software package for three-dimensional display from computed tomograms,” Proc. SPIE 0515, 309 (1984). 10.1117/12.964778 [DOI] [Google Scholar]

[r50] 50.Risser T., “Distributed image processing and analysis for PACS,” Proc. SPIE 0515, 61 (1984). 10.1117/12.964730 [DOI] [Google Scholar]

[r51] 51.Hedge S. S., Prewitt J. M. S., “A layered approach to PACS network architecture,” Proc. SPIE 0515, 442 (1984). 10.1117/12.964803 [DOI] [Google Scholar]

[r52] 52.Shum C. D., et al. , “Design analysis of a wide-band picture communication system,” Proc. SPIE 0515, 66 (1984). 10.1117/12.964732 [DOI] [Google Scholar]

[r53] 53.Birkner D. A., “Design considerations for a user oriented PACS,” Proc. SPIE 0515, 89 (1984). 10.1117/12.964734 [DOI] [Google Scholar]

[r54] 54.Hindel R., et al. , “Conceptual models for interactions with PACS,” Proc. SPIE 0515, 145 (1984). 10.1117/12.964744 [DOI] [Google Scholar]

[r55] 55.Bergey P., et al. , “A linear systems approach to medical image capture and display,” Proc. SPIE 0515, 4 (1984). 10.1117/12.964716 [DOI] [Google Scholar]

[r56] 56.Cambier J. L., et al. , “Image acquisition and storage for ophthalmic fluorescein angiography,” Proc. SPIE 0515, 224 (1984). 10.1117/12.964762 [DOI] [Google Scholar]

[r57] 57.Prewitt J. M. S., et al. , “Name-value pair specification for image data headers and logical standards for image data exchange,” Proc. SPIE 0515, 452 (1984). 10.1117/12.964804 [DOI] [Google Scholar]

[r58] 58.Gray M. J., Rutherford H., “Functional specifications of a useful digital multimodality image workstation,” Proc. SPIE 0515, 8 (1984). 10.1117/12.964717 [DOI] [Google Scholar]

[r59] 59.Fisher H. D., et al. , “Psychophysical evaluation of the spatial and contrast resolution necessary for a picture archiving and communication system: works in progress,” Proc. SPIE 0515, 13 (1984). 10.1117/12.964718 [DOI] [Google Scholar]

[r60] 60.Perry J. R., et al. , “Digital image display console design issues,” Proc. SPIE 0515, 18 (1984). 10.1117/12.964719 [DOI] [Google Scholar]

[r61] 61.Obayashi I., et al. , “Network analysis of picture archiving and communication system,” Proc. SPIE 0515, 109 (1984). 10.1117/12.964737 [DOI] [Google Scholar]

[r62] 62.Kato H., Kita K., “Toshiba optical disk stores 15000 CT images,” Proc. SPIE 0515, 138 (1984). 10.1117/12.964742 [DOI] [Google Scholar]

[r63] 63.Vanden Brink J. A., “The commercial challenges of PACS,” Proc. SPIE 0515, 440 (1984). 10.1117/12.964802 [DOI] [Google Scholar]

[r64] 64.Okagaki T., et al. , “On-line archiving and enhancement of diagnostic electron microscope images in medicine,” Proc. SPIE 0515, 161 (1984). 10.1117/12.964748 [DOI] [Google Scholar]

[r65] 65.Beltrame F., et al. , “Three dimensional imaging of cells through digital holographic microscopy,” Proc. SPIE 0515, 232 (1984). 10.1117/12.964763 [DOI] [Google Scholar]

[r66] 66.Bunke H., et al. , “Artificial intelligence and image understanding methods in a system for the automatic diagnostic evaluation of technetium 99-M gated blood pool studies,” Proc. SPIE 0515, 417 (1984). 10.1117/12.964796 [DOI] [Google Scholar]

[r67] 67.Wang Y., et al. , “Overview of ACR-NEMA digital imaging and communication standard,” Proc. SPIE 0536, 132 (1985). 10.1117/12.947341 [DOI] [Google Scholar]

[r68] 68.Lawrence G. R., “ACR/NEMA digital image interface standard (an illustrated protocol overview),” Proc. SPIE 0536, 139 (1985). 10.1117/12.947343 [DOI] [Google Scholar]

[r69] 69.Dwyer S. J., et al. , “A study of archiving requirements for a Radiology Department,” Proc. SPIE 0536, 190 (1985). 10.1117/12.947356 [DOI] [Google Scholar]

[r70] 70.Siebert J. E., et al. , “Communication network for metropolitan area interhospital image exchange,” Proc. SPIE 0536, 3 (1985). 10.1117/12.947322 [DOI] [Google Scholar]

[r71] 71.Lo S. C. B., Huang H. K., “Error-free and irreversible radiographic image compression,” Proc. SPIE 0536, 170 (1985). 10.1117/12.947351 [DOI] [Google Scholar]

[r72] 72.Moran P. R., “Eigen-representations, data compression and transmission for medical images and related structures,” Proc. SPIE 0536, 183 (1985). 10.1117/12.947355 [DOI] [Google Scholar]

[r73] 73.Murphy R. E., Lau R., “Very high resolution interactive medical display system,” Proc. SPIE 0536, 57 (1985). 10.1117/12.947330 [DOI] [Google Scholar]

[r74] 74.Horii S. C., et al. , “Design considerations for image viewstations,” Proc. SPIE 0536, 80 (1985). 10.1117/12.947333 [DOI] [Google Scholar]

[r75] 75.Maydell U. M., Davis W. A., “Simulation of an interactive workstation for image display,” Proc. SPIE 0536, 110 (1985). 10.1117/12.947337 [DOI] [Google Scholar]

[r76] 76.Gray M. J., et al. , “Features of a networked medical image workstation called M/Net,” Proc. SPIE 0536, 117 (1985). 10.1117/12.947338 [DOI] [Google Scholar]

[r77] 77.Massicotte J. B., et al. , “A menu-driven user interface for a physician’s imaging console,” Proc. SPIE 0536, 158 (1985). 10.1117/12.947347 [DOI] [Google Scholar]

[r78] 78.Janjua A., Racionzer D., “A multimodality image display and image processing system,” Proc. SPIE 0536, 165 (1985). 10.1117/12.947349 [DOI] [Google Scholar]

[r79] 79.Lehr J. L., “Comparison exam: impact on PACS,” Proc. SPIE 0536, 126 (1985). 10.1117/12.947340 [DOI] [Google Scholar]

[r80] 80.Benson H. R., et al. , “Integration of radiological reporting systems (RRS) into a picture archiving and communication systems (PACS),” Proc. SPIE 0536, 214 (1985). 10.1117/12.947364 [DOI] [Google Scholar]

[r81] 81.Fisher J. H., Vittori W., “The clinical workstation: integration of medical images into clinical care,” Proc. SPIE 0536, 148 (1985). 10.1117/12.947344 [DOI] [Google Scholar]

[r82] 82.Mun S. K., et al. , “Development of PACS at Georgetown University Radiology Department,” Proc. SPIE 0536, 229 (1985). 10.1117/12.947366 [DOI] [Google Scholar]

[r83] 83.Thompson B. G., et al. , “PACS: part of an integrated communications system,” Proc. SPIE 0536, 237 (1985). 10.1117/12.947368 [DOI] [Google Scholar]

[r84] 84.Cywinski J. K., et al. , “Cost-benefit implications of automated PACS for digital modalities,” Proc. SPIE 0536, 15 (1985). 10.1117/12.947324 [DOI] [Google Scholar]

[r85] 85.Johnston R. E., et al. , “Perceptual standardization,” Proc. SPIE 0536, 44 (1985). 10.1117/12.947328 [DOI] [Google Scholar]

[r86] 86.Shalev S., et al. , “Pseudo-3D imaging with the DICOM-8,” Proc. SPIE 0555, 63 (1985). 10.1117/12.949477 [DOI] [Google Scholar]

[r87] 87.Mun S. K., et al. , “Design and implementation of PACS at Georgetown University Hospital,” Proc. SPIE 0555, 217 (1985). 10.1117/12.949497 [DOI] [Google Scholar]

[r88] 88.Stockbridge C., Ravin C. E., “Phased implementation of AT&T PACS at Duke University Medical Center,” Proc. SPIE 0671, 169 (1986). 10.1117/12.966692 [DOI] [Google Scholar]

[r89] 89.Lubinsky A. R., et al. , “Storage phosphor system for computed radiography: optical effects and detective quantum efficiency (DQE),” Proc. SPIE 0767, 167 (1987). 10.1117/12.966995 [DOI] [Google Scholar]

[r90] 90.Yorker J. G., “Photostimulated luminescence digital radiography system characterization II: Image quality measurements,” Proc. SPIE 0767, 162 (1987). 10.1117/12.966994 [DOI] [Google Scholar]

[r91] 91.Blume H., Kamiya K., “Auto-ranging and normalization versus histogram modifications for automatic image processing of digital radiographs,” Proc. SPIE 0767, 371 (1987). 10.1117/12.967021 [DOI] [Google Scholar]

[r92] 92.Nelson R. S., et al. , “Digital slot scan mammography using CCDs,” Proc. SPIE 0767, 102 (1987). 10.1117/12.966986 [DOI] [Google Scholar]

[r93] 93.Stewart B. K., Huang H. K., “Dual energy radiography using a single exposure technique,” Proc. SPIE 0767, 154 (1987). 10.1117/12.966993 [DOI] [Google Scholar]

[r94] 94.Horii S. C., et al. , “The ACR-NEMA exchange medial standards: progress and future directions,” Proc. SPIE 0767, 272 (1987). 10.1117/12.967006 [DOI] [Google Scholar]

[r95] 95.Ho B. K. T., et al. , “Expandable image compression system: a modular approach,” Proc. SPIE 0767, 286 (1987). 10.1117/12.967008 [DOI] [Google Scholar]

[r96] 96.van Aken I. W., et al. , “Compressed medical images and enhanced fault detection with an ACR-NEMA compatible picture archiving and communications system,” Proc. SPIE 0767, 290 (1987). 10.1117/12.967009 [DOI] [Google Scholar]

[r97] 97.Giger M. L., et al. , “Computerized detection of lung nodules in digital chest radiographs,” Proc. SPIE 0767, 384 (1987). 10.1117/12.967022 [DOI] [Google Scholar]

[r98] 98.Pond G. D., et al. , “Comparison of conventional film/screen to photo-stimulable imaging plate radiographs for intraoperative arteriography and cholangiography,” Proc. SPIE 0914, 139 (1988). 10.1117/12.968625 [DOI] [Google Scholar]

[r99] 99.Tecotzky M., Andrews-Eurglunes C., “Storage phosphors for medical imaging I: quality assurance considerations and variations in quality,” Proc. SPIE 0914, 143 (1988). 10.1117/12.968626 [DOI] [Google Scholar]

[r100] 100.Yaffe M., et al. , “Development of a digital mammography system,” Proc. SPIE 0914, 182 (1988). 10.1117/12.968631 [DOI] [Google Scholar]

[r101] 101.Shaber G. S., Lockard C., Boone H. M., “High resolution digital radiography utilizing CCD planar array,” Proc. SPIE 0914, 262 (1988). 10.1117/12.968640 [DOI] [Google Scholar]

[r102] 102.Yamasaki K., et al. , “Diagnostic capability of digital chest images,” Proc. SPIE 0914, 577 (1988). 10.1117/12.968683 [DOI] [Google Scholar]

[r103] 103.Shaber G. S., et al. , “ROC detectability evaluation of a filmless digital radiographic system,” Proc. SPIE 0914, 560 (1988). 10.1117/12.968681 [DOI] [Google Scholar]

[r104] 104.Ho B. K. T., et al. , “High speed image compression system, prototype and final configuration,” Proc. SPIE 0914, 786 (1988). 10.1117/12.968714 [DOI] [Google Scholar]

[r105] 105.Blume H., et al. , “The ACR-NEMA digital interface communications standard to compression techniques: status report,” Proc. SPIE 0914, 823 (1988). 10.1117/12.968718 [DOI] [Google Scholar]

[r106] 106.Lo S. C. B., Mun S. K., “Data compression for a radiology image display system with visual directory,” Proc. SPIE 0914, 1203 (1988). 10.1117/12.968767 [DOI] [Google Scholar]

[r107] 107.McNeill K. M., et al. , “Comparison of digital workstations and conventional reading for evaluation of user interfaces in digital radiology,” Proc. SPIE 0914, 872 (1988). 10.1117/12.968724 [DOI] [Google Scholar]

[r108] 108.Fahy J. B., Kim Y., “A consistent DIN/PACS workstation interface based on the MUVIP virtual image processing architecture,” Proc. SPIE 0914, 911 (1988). 10.1117/12.968729 [DOI] [Google Scholar]

[r109] 109.Horii S. C., et al. , “An eclectic look at viewing station design,” Proc. SPIE 0914 (1988). 10.1117/12.968730 [DOI] [Google Scholar]

[r110] 110.McNeill K. M., et al. , “Comparison of a digital workstation and a film alternator,” Proc. SPIE 0914, 929 (1988). 10.1117/12.968731 [DOI] [Google Scholar]

[r111] 111.Beard D., et al. , “Experiment comparing film and the filmplane radiology workstation,” Proc. SPIE 0914, 933 (1988). 10.1117/12.968732 [DOI] [Google Scholar]

[r112] 112.O’Malley K. G., Giunta J. A., “The alternator: determination of its fundamental features as a basis for design of a PACS diagnostic workstation,” Proc. SPIE 0914, 988 (1988). 10.1117/12.968739 [DOI] [Google Scholar]

[r113] 113.Kishore S., Seshadri S. B., Arenson R. L., “A MIMS view-station for orthopedic images,” Proc. SPIE 0914, 1023 (1988). 10.1117/12.968743 [DOI] [Google Scholar]

[r114] 114.Cox J. R., et al. , “An inexpensive electronic viewbox,” Proc. SPIE 0914, 1218 (1988). 10.1117/12.968769 [DOI] [Google Scholar]

[r115] 115.Kim Y., et al. , “Development of a PC-based radiologic imaging workstation,” Proc. SPIE 0914, 1257 (1988). 10.1117/12.968774 [DOI] [Google Scholar]

[r116] 116.Humphrey L. M., Ravin C. E., “Film traffic queuing model for the DUMC Radiology Department,” Proc. SPIE 0914, 947 (1988). 10.1117/12.968734 [DOI] [Google Scholar]

[r117] 117.Blaine G. J., et al. , “Image transmission studies,” Proc. SPIE 0914, 953 (1988). 10.1117/12.968735 [DOI] [Google Scholar]

[r118] 118.Seshadri S. B., et al. , “Satellite transmission of medical images,” Proc. SPIE 0914, 1416 (1988). 10.1117/12.968799 [DOI] [Google Scholar]

[r119] 119.List J. S., O’Malley K. G., “The impact of PACS technology on diagnostic cycle time,” Proc. SPIE 0914, 961 (1988). 10.1117/12.968736 [DOI] [Google Scholar]

[r120] 120.Mun S. K., et al. , “Baseline study of radiology services for the purpose of PACS evaluation,” Proc. SPIE 0914, 978 (1988). 10.1117/12.968738 [DOI] [Google Scholar]

[r121] 121.ter Haar Romeny B. M., et al. , “Procedures to study the impact of PACS on the logistics within a Diagnostic Imaging Department,” Proc. SPIE 0914, 1159 (1988). 10.1117/12.968760 [DOI] [Google Scholar]

[r122] 122.Benson H. R., et al. , “Cost analysis for the development of digital imaging network,” Proc. SPIE 0914, 1008 (1988). 10.1117/12.968742 [DOI] [Google Scholar]

[r123] 123.Bakker A. R., et al. , “PACS costs: modeling and simulation,” Proc. SPIE 0914, 1147 (1988). 10.1117/12.968758 [DOI] [Google Scholar]

[r124] 124.Kangarloo H., et al. , “Clinical experience with a PACS module in pediatric radiology: clinical viewpoint,” Proc. SPIE 0914, 1036 (1988). 10.1117/12.968744 [DOI] [Google Scholar]

[r125] 125.Taira R. K., Mankovich N. J., Huang H. K., “One-year experience with a PACS module in pediatric radiology: system viewpoint,” Proc. SPIE 0914, 1046 (1988). 10.1117/12.968745 [DOI] [Google Scholar]

[r126] 126.Cho P. S., Huang H. K., Tillisch J., “Clinical experience with a digital remote viewing system in coronary care unit,” Proc. SPIE 0914, 1057 (1988). 10.1117/12.968746 [DOI] [Google Scholar]

[r127] 127.Greberman M., et al. , “The collaborative digital imaging network project,” Proc. SPIE 0914, 1326 (1988). 10.1117/12.968784 [DOI] [Google Scholar]

[r128] 128.Cerva J., et al. , “Integration of digital imaging network technology into the US Army’s Fixed Facility and Deployable Medical Centers,” Proc. SPIE 0914, 1328 (1988). 10.1117/12.968785 [DOI] [Google Scholar]

[r129] 129.Mun S. K., et al. , “Development and operational evaluation of PACS network at Georgetown University,” Proc. SPIE 0914, 1334 (1988). 10.1117/12.968786 [DOI] [Google Scholar]

[r130] 130.Haynor D. R., Rowberg A. H., Loop J. W., “Clinical evaluation of a prototype digital imaging network,” Proc. SPIE 0914, 1341 (1988). 10.1117/12.968787 [DOI] [Google Scholar]

[r131] 131.Creasy J. L., et al. , “Overview of University of North Carolina at Chapel Hill PACS program,” Proc. SPIE 0914, 1349 (1988). 10.1117/12.968789 [DOI] [Google Scholar]

[r132] 132.Minato K., Komori M., Nakano Y., “Experience with a small scale all digital CT and MRI clinical service unit: present status of Kyoto University Hospital Image Database and Communication System,” Proc. SPIE 0914, 1356 (1988). 10.1117/12.968790 [DOI] [Google Scholar]

[r133] 133.Nosil J., et al. , “A prototype multi-modality picture archive and communication system at Victoria General Hospital,” Proc. SPIE 0914, 1362 (1988). 10.1117/12.968791 [DOI] [Google Scholar]

[r134] 134.Ratib O. M., et al. , “Integration of an MR image network into a clinical PACS,” Proc. SPIE 0914, 1379 (1988). 10.1117/12.968793 [DOI] [Google Scholar]

[r135] 135.Suzuki M., et al. , “Clinical evaluation of TDF-500 system,” Proc. SPIE 0914, 1398 (1988). 10.1117/12.968796 [DOI] [Google Scholar]

[r136] 136.Butler D. M., Hamilton C. L., “A prototype relational implementation of the ‘NEMA schema’,” Proc. SPIE 0914, 1066 (1988). 10.1117/12.968747 [DOI] [Google Scholar]

[r137] 137.Ringleben C. L., et al. , “An ACR-NEMA implementation and PACS architectural implication,” Proc. SPIE 0914, 1069 (1988). 10.1117/12.968748 [DOI] [Google Scholar]

[r138] 138.Good W. F., et al. , “ACR-NEMA standard: the reality versus the ideal,” Proc. SPIE 0914, 1081 (1988). 10.1117/12.968749 [DOI] [Google Scholar]

[r139] 139.Awang Y., et al. , “Update of the ACR-NEMA standard committee,” Proc. SPIE 0914, 1406 (1988). 10.1117/12.968797 [DOI] [Google Scholar]

[r140] 140.Seshadri S. B., et al. , “An image archive with the ACR-NEMA message formats,” Proc. SPIE 0914, 1409 (1988). 10.1117/12.968798 [DOI] [Google Scholar]

[r141] 141.Kerlin B. D., “The optical memory card as a transportable image archiving medium in a digital imaging network,” Proc. SPIE 0914, 1088 (1988). 10.1117/12.968750 [DOI] [Google Scholar]

[r142] 142.Fisher P. D., et al. , “Clinically-based archive model for a picture archive and communication system,” Proc. SPIE 0914, 1097 (1988). 10.1117/12.968751 [DOI] [Google Scholar]

[r143] 143.Mankovich N. J., et al. , “Procedures, films and images in a pediatric radiology image archive: one year’s experience and projections,” Proc. SPIE 0914, 1106 (1988). 10.1117/12.968752 [DOI] [Google Scholar]

[r144] 144.Martinez R., Nemat M., “Image data base archive design using parallel architectures and expert systems,” Proc. SPIE 0914, 1114 (1988). 10.1117/12.968753 [DOI] [Google Scholar]

[r145] 145.Kamm K. F., et al. , “Digital image archiving and handling – status and trends,” Proc. SPIE 0914, 1171 (1988). 10.1117/12.968762 [DOI] [Google Scholar]

[r146] 146.Cohen J., et al. , “A laser disk-based archive, review and communications system for magnetic resonance imaging,” Proc. SPIE 0914, 1344 (1988). 10.1117/12.968788 [DOI] [Google Scholar]

[r147] 147.Lodder H., et al. , “HIS-PACS coupling: first experiences,” Proc. SPIE 0914, 1141 (1988). 10.1117/12.968757 [DOI] [Google Scholar]

[r148] 148.Paisner M. W., “Radiology operations systems,” Proc. SPIE 0914, 1391 (1988). 10.1117/12.968795 [DOI] [Google Scholar]

[r149] 149.Barneveld Binkhuysen F. H., et al. , “First results of the diagnostic evaluation studies and the clinical efficacy evaluation in the Dutch PACS project,” Proc. SPIE 1093, 13 (1989). 10.1117/12.953312 [DOI] [Google Scholar]

[r150] 150.Minato K., et al. , “PACS development at Kyoto University Hospital: toward integrating digital imaging modalities,” Proc. SPIE 1093, 20 (1989). 10.1117/12.953313 [DOI] [Google Scholar]

[r151] 151.Lou S. L., et al. , “A CT/MR/US picture archiving and communication system,” Proc. SPIE 1093, 31 (1989). 10.1117/12.953315 [DOI] [Google Scholar]

[r152] 152.Arenson R. L., et al. , “PACS at Penn,” Proc. SPIE 1093, 50 (1989). 10.1117/12.953317 [DOI] [Google Scholar]

[r153] 153.Mun S. K., et al. , “Total digital department: implementation strategy,” Proc. SPIE 1093, 133 (1989). 10.1117/12.953326 [DOI] [Google Scholar]

[r154] 154.Cho P. S., Huang H. K., Tillisch J., “Centralized versus distributed PACS for intensive care units,” Proc. SPIE 1093, 387 (1989). 10.1117/12.953352 [DOI] [Google Scholar]

[r155] 155.Taira R. K., et al. , “Performance evaluation of a clinical PACS module,” Proc. SPIE 1093, 406 (1989). 10.1117/12.953355 [DOI] [Google Scholar]

[r156] 156.Jost R. G., et al. , “PACS – is there light at the end of the tunnel?” Proc. SPIE 1093, 74 (1989). 10.1117/12.953319 [DOI] [Google Scholar]

[r157] 157.Seeley G. W., et al. , “Evaluation of the DuPont teleradiology system,” Proc. SPIE 1093, 106 (1989). 10.1117/12.953322 [DOI] [Google Scholar]

[r158] 158.Horii S. C., et al. , “A complete image management and communications network for the neuroradiology service at Georgetown University Hospital,” Proc. SPIE 1093, 154 (1989). 10.1117/12.953328 [DOI] [Google Scholar]

[r159] 159.Saarienen A. O., Goodsitt M. M., Loop J. W., “The logistics of installing PACS in an Existing Medical Center,” Proc. SPIE 1093, 159 (1989). 10.1117/12.953329 [DOI] [Google Scholar]

[r160] 160.Mun S. K., et al. , “Experience with image management networks at three universities: is the cup half-empty or half-full?” Proc. SPIE 1093, 194 (1989). 10.1117/12.953332 [DOI] [PMC free article] [PubMed] [Google Scholar]

[r161] 161.ter Haar Romeny B. M., et al. , “PACS efficiency: a detailed quantitative study of the distribution process of films in a clinical environment in the Utrecht University Hospital,” Proc. SPIE 1093, 259 (1989). 10.1117/12.953339 [DOI] [Google Scholar]

[r162] 162.Goeringer F., Mun S. K., Kerlin B. D., “Digital medical imaging: implementation strategy for the defense medical establishment,” Proc. SPIE 1093, 429 (1989). 10.1117/12.953358 [DOI] [Google Scholar]

[r163] 163.Siedband M., et al. , “Filmless radiographic system for Army Field Hospitals,” Proc. SPIE 1093, 466 (1989). 10.1117/12.953362 [DOI] [Google Scholar]

[r164] 164.Nadel L. D., et al. , “Prototype system for digital image management in Combat casualty care,” Proc. SPIE 1093, 511 (1989). 10.1117/12.953367 [DOI] [Google Scholar]

[r165] 165.Andriessen J. H. T. H., et al. , “Methodology of PACS effectiveness evaluation as part of a technology assessment: the Dutch PACS project extrapolated,” Proc. SPIE 1093, 585 (1989). 10.1117/12.953377 [DOI] [Google Scholar]

[r166] 166.Mankovich N. J., Taira R. K., “Image archiving hardware and database technology,” Proc. SPIE 1093, 244 (1989). 10.1117/12.953337 [DOI] [Google Scholar]

[r167] 167.Britt M. O., et al. , “Optical archive organization and strategies for the 1990s,” Proc. SPIE 1093, 498 (1989). 10.1117/12.953365 [DOI] [Google Scholar]

[r168] 168.Hedgcock M. W., Levitt T. S., Smith S., “Calculating storage needs for an optical archive,” Proc. SPIE 1093, 551 (1989). 10.1117/12.953372 [DOI] [Google Scholar]

[r169] 169.Martinez R., Nematbakhsh M., “Design and performance evaluation of a high speed fiber optic integrated computer network for a picture archiving and communications system,” Proc. SPIE 1093, 37 (1989). 10.1117/12.953316 [DOI] [Google Scholar]

[r170] 170.Dallas W. J., et al. , “A fiber-optic network system for PACS,” Proc. SPIE 1093, 85 (1989). 10.1117/12.953320 [DOI] [Google Scholar]

[r171] 171.Reijns G. L., et al. , “Performance aspects of a PACS using a hardware implemented ACR-NEMA interface for medical image exchange,” Proc. SPIE 1093, 171 (1989). 10.1117/12.953330 [DOI] [Google Scholar]

[r172] 172.Gee J. C., et al. , “User interface design for a radiological imaging workstation,” Proc. SPIE 1093, 122 (1989). 10.1117/12.953325 [DOI] [Google Scholar]

[r173] 173.Belanger G., et al. , “Evaluation of a workstation by clinicians,” Proc. SPIE 1093, 214 (1989). 10.1117/12.953334 [DOI] [Google Scholar]

[r174] 174.Braudes R. E., et al. , “Workstation modelling and development: clinical definition of a picture archiving and communications system (PACS) user interface,” Proc. SPIE 1093, 376 (1989). 10.1117/12.953351 [DOI] [Google Scholar]

[r175] 175.Dullien R., “Progress in PACS – definition of the principal workstation types,” Proc. SPIE 1093, 438 (1989). 10.1117/12.953359 [DOI] [Google Scholar]

[r176] 176.Levine B., et al. , “Integration of a RIS with an IMACS,” Proc. SPIE 1093, 183 (1989). 10.1117/12.953331 [DOI] [Google Scholar]

[r177] 177.Lodder H., et al. , “HIS-PACS coupling in practice,” Proc. SPIE 1093, 301 (1989). 10.1117/12.953343 [DOI] [Google Scholar]

[r178] 178.Boehme J. M., Choplin T. H., Maynard C. D., “Early experience in interfacing PACS to RIS,” Proc. SPIE 1093, 589 (1989). 10.1117/12.953378 [DOI] [Google Scholar]

[r179] 179.Saarinen A. O., et al. , “Modeling the economics of PACS: what is important?” Proc. SPIE 1093, 62 (1989). 10.1117/12.953318 [DOI] [Google Scholar]

[r180] 180.Benson H., et al. , “CAMDIN a cost analysis model for digital imaging networks,” Proc. SPIE 1093, 448 (1989). 10.1117/12.953360 [DOI] [Google Scholar]

[r181] 181.Parrish D. M., et al. , “Operational modeling for PACS: how do we decide if it’s cost effective?” Proc. SPIE 1093, 457 (1989). 10.1117/12.953361 [DOI] [Google Scholar]

[r182] 182.Cywinski J. K., Vanden Brink J. A., “Review of experience with PACS cost analysis model,” Proc. SPIE 1093, 535 (1989). 10.1117/12.953369 [DOI] [Google Scholar]

[r183] 183.Bakker A. R., et al. , “Cost modelling of PACS,” Proc. SPIE 1093, 545 (1989). 10.1117/12.953371 [DOI] [Google Scholar]

[r184] 184.Andriessen J. H. T. H., et al. , “Savings and costs of a picture archiving and communication system in the University Hospital Utrecht,” Proc. SPIE 1093, 578 (1989). 10.1117/12.953376 [DOI] [Google Scholar]

[r185] 185.Beard D. V., et al. , “Cost analysis of film image management and four PACS systems,” Proc. SPIE 1234, 10 (1990). 10.1117/12.18938 [DOI] [PubMed] [Google Scholar]

[r186] 186.Saarienen A. O., et al. , “Potential time savings to radiology department personnel in a PACS-based environment,” Proc. SPIE 1234, 823 (1990). 10.1117/12.19010 [DOI] [Google Scholar]

[r187] 187.Kundel H. L., Seshadri S. B., Arenson R. L., “Clinical evaluation of PACS: modeling diagnostic value,” Proc. SPIE 1234, 214 (1990). 10.1117/12.19030 [DOI] [Google Scholar]

[r188] 188.Haynor D. R., et al. , “Clinical evaluation of PACS workstations: methodology and results,” Proc. SPIE 1234, 408 (1990). 10.1117/12.19044 [DOI] [Google Scholar]

[r189] 189.Razavi M., et al. , “Display conditions and lesion detectability: effect of background light,” Proc. SPIE 1234, 776 (1990). 10.1117/12.19004 [DOI] [Google Scholar]

[r190] 190.Hedgcock M. W., et al. , “Image degradation in PACS,” Proc. SPIE 1234, 933 (1990). 10.1117/12.19027 [DOI] [Google Scholar]

[r191] 191.Taira R. K., et al. , “High-resolution workstations for primary and secondary radiology readings,” Proc. SPIE 1234, 18 (1990). 10.1117/12.18939 [DOI] [Google Scholar]

[r192] 192.Good W. F., et al. , “Implementation of a high-resolution workstation for primary diagnosis of projection radiography images,” Proc. SPIE 1234, 105 (1990). 10.1117/12.18950 [DOI] [Google Scholar]

[r193] 193.Dwyer S. J., III, et al. , “Experience with high-resolution digital gray-scale display systems,” Proc. SPIE 1234, 132 (1990). 10.1117/12.18966 [DOI] [Google Scholar]

[r194] 194.Hall C. L., Perry J. H., “Siemens experience in PACS,” Proc. SPIE 1234, 354 (1990). 10.1117/12.19060 [DOI] [Google Scholar]

[r195] 195.Morin R. L., et al. , “New AS/400-based PACS for MRI and CT,” Proc. SPIE 1234, 326 (1990). 10.1117/12.19041 [DOI] [Google Scholar]

[r196] 196.Weinberg W. S., et al. , “Development and implementation of ultrasound picture archiving and communication system,” Proc. SPIE 1234, 44 (1990). 10.1117/12.18942 [DOI] [Google Scholar]

[r197] 197.Horii S. C., et al. , “Validating simulation: comparison of a PACS network model of ultrasound image acquisition with actual performance,” Proc. SPIE 1234, 205 (1990). 10.1117/12.19024 [DOI] [Google Scholar]

[r198] 198.Blaine G. J., et al. , “ISDN: early experiments as a wide-area extension to LAN-based PACS,” Proc. SPIE 1234, 140 (1990). 10.1117/12.18973 [DOI] [Google Scholar]

[r199] 199.Prior F. W., et al. , “Impact of node architecture on network performance,” Proc. SPIE 1234, 334 (1990). 10.1117/12.19042 [DOI] [Google Scholar]

[r200] 200.Wong A. W. K., et al. , “Performance comparisons of image communication networks,” Proc. SPIE 1234, 461 (1990). 10.1117/12.19051 [DOI] [Google Scholar]

[r201] 201.DeJarnette W. T., “Two chip ACR-NEMA datalink/physical layer implementation,” Proc. SPIE 1234, 541 (1990). 10.1117/12.18967 [DOI] [Google Scholar]

[r202] 202.Kofakis P. G., et al. , “Image archiving by content: an object-oriented approach,” Proc. SPIE 1234, 275 (1990). 10.1117/12.19037 [DOI] [Google Scholar]

[r203] 203.Seshadri S. B., et al. , “Software considerations in the design of an image archive,” Proc. SPIE 1234, 2 (1990). 10.1117/12.19052 [DOI] [Google Scholar]

[r204] 204.D’Lugin J. J., et al. , “Optimization of image transfer from the central archive to workstations in a PACS,” Proc. SPIE 1234, 398 (1990). 10.1117/12.19059 [DOI] [Google Scholar]

[r205] 205.Seshadri S. B., et al. , “Architecture of an optical jukebox image archive,” Proc. SPIE 1234, 925 (1990). 10.1117/12.19025 [DOI] [Google Scholar]

[r206] 206.Cooperstein L. A., et al. , “Incorporation of a clinical history into the interpretation process in a PACS environment,” Proc. SPIE 1234, 98 (1990). 10.1117/12.18949 [DOI] [Google Scholar]

[r207] 207.Levin K., Fielding R., “Methods to prefetch comparison images in image management and communication system,” Proc. SPIE 1234, 270 (1990). 10.1117/12.19036 [DOI] [Google Scholar]

[r208] 208.Levine B. A., et al. , “Assessment of the integration of a HIS/RIS With a PACS,” Proc. SPIE 1234, 391 (1990). 10.1117/12.19057 [DOI] [Google Scholar]

[r209] 209.Lee W., et al. , “Integrating a radiology information system with a picture archiving and communications system,” Proc. SPIE 1234, 661 (1990). 10.1117/12.18987 [DOI] [Google Scholar]

[r210] 210.Jost R. G., et al. , “High-resolution teleradiology applications within the hospital,” Proc. SPIE 1446, 2 (1991). 10.1117/12.27713 [DOI] [Google Scholar]

[r211] 211.Staab E. V., et al. , “Teleradiology in the local environment,” Proc. SPIE 1446, 16 (1991). 10.1117/12.45257 [DOI] [Google Scholar]

[r212] 212.Morin R. L., et al. , “Present status and future directions of the Mayo/IBM PACS project,” Proc. SPIE 1446, 436 (1991). 10.1117/12.45302 [DOI] [Google Scholar]

[r213] 213.Ratib O. M., et al. , “Hospital-integrated PACS at the University Hospital of Geneva,” Proc. SPIE 1446, 330 (1991). 10.1117/12.45289 [DOI] [Google Scholar]

[r214] 214.Kouwenberg J. M. L., Ottes F. P., Bakker A. R., “European activities towards a hospital-integrated PACS based on open systems,” Proc. SPIE 1446, 357 (1991). 10.1117/12.45292 [DOI] [Google Scholar]

[r215] 215.Razavi M., et al. , “Clinical evaluation of a 2K x 2K workstation for primary diagnosis in pediatric radiology,” Proc. SPIE 1446, 24 (1991). 10.1117/12.27720 [DOI] [Google Scholar]

[r216] 216.Beard D. V., et al. , “Radiology workstation for mammography: preliminary observations, eyetracker studies and design,” Proc. SPIE 1446, 289 (1991). 10.1117/12.45284 [DOI] [Google Scholar]

[r217] 217.Wong A. W. K., et al. , “Multiple communication networks for a radiological PACS,” Proc. SPIE 1446, 73 (1991). 10.1117/12.45262 [DOI] [Google Scholar]

[r218] 218.Chimiak W. J., Williams R. C., “Using the ACR/NEMA standard with TCP/IP and ethernet,” Proc. SPIE 1446, 93 (1991). 10.1117/12.45263 [DOI] [Google Scholar]

[r219] 219.Stewart B. K., et al. , “Performance characteristics of an ultra-fast network for PACS,” Proc. SPIE 1446, 141 (1991). 10.1117/12.45267 [DOI] [Google Scholar]

[r220] 220.Taira R. K., et al. , “Reliability issues in PACS,” Proc. SPIE 1446, 451 (1991). 10.1117/12.45304 [DOI] [Google Scholar]

[r221] 221.Horii S. C., et al. , “PACS reading time comparison: the workstation versus alternator for ultrasound,” Proc. SPIE 1446, 475 (1991). 10.1117/12.45310 [DOI] [Google Scholar]

[r222] 222.Umeda T., et al. , “Multi-media PACS integrated with HIS/RIS employing magneto-optical disks,” Proc. SPIE 1446, 199 (1991). 10.1117/12.45273 [DOI] [Google Scholar]

[r223] 223.Feingold E. R., Seshadri S. B., Arenson R. L., “Folder management on a multimodality PACS display station,” Proc. SPIE 1446, 211 (1991). 10.1117/12.45274 [DOI] [Google Scholar]

[r224] 224.Lodder H., et al. , “Prefetching: PACS image management optimization using HIS/RIS information,” Proc. SPIE 1446, 227 (1991). 10.1117/12.45276 [DOI] [Google Scholar]

[r225] 225.Dayhoff R. E., et al. , “Experiences with a comprehensive hospital information system that incorporates image management capabilities,” Proc. SPIE 1446, 323 (1991). 10.1117/12.45288 [DOI] [Google Scholar]

[r226] 226.King J. L., et al. , “Radiologists’ confidence in detecting abnormalities on chest images and their subjective judgements of image quality,” Proc. SPIE 1446, 268 (1991). 10.1117/12.45281 [DOI] [Google Scholar]

[r227] 227.van Gennip E. M. S. J., et al. , “Comparison of worldwide opinions on the costs and benefits of PACS,” Proc. SPIE 1446, 442 (1991). 10.1117/12.45303 [DOI] [Google Scholar]

[r228] 228.Rundle D. A., et al. , “DRILL: a standardized radiology-teaching knowledge base,” Proc. SPIE 1446, 405 (1991). 10.1117/12.45297 [DOI] [Google Scholar]

[r229] 229.Wong A. W. K., et al. , “On-line performance characteristics of a radiology PACS,” Proc. SPIE 1654, 14 (1992). 10.1117/12.60255 [DOI] [Google Scholar]

[r230] 230.Eldredge S. L., et al. , “Operation of a clinical PACS,” Proc. SPIE 1654, 349 (1992). 10.1117/12.60287 [DOI] [Google Scholar]

[r231] 231.Lou S. A., Huang H. K., “Clinical assessment of a neuroradiology PACS,” Proc. SPIE 1654, 373 (1992). 10.1117/12.60289 [DOI] [Google Scholar]

[r232] 232.Honeyman-Buck J. C., et al. , “PACS in clinical neuroradiology, nuclear medicine and teleradiology,” Proc. SPIE 1654, 383 (1992). 10.1117/12.60290 [DOI] [Google Scholar]

[r233] 233.Fritz S. L., DeJarnette W. T., “Design of a multivendor PACS network for a university hospital environment,” Proc. SPIE 1654, 559 (1992). 10.1117/12.60313 [DOI] [Google Scholar]

[r234] 234.Bryan S., et al. , “Evaluation of a hospital-wide PACS: costs and benefits of the Hammersmith PACS instillation,” Proc. SPIE 1654, 573 (1992). 10.1117/12.60317 [DOI] [Google Scholar]

[r235] 235.Smith D. V., et al. , “Design strategy and implementation of the medical diagnostic image support system at two large military medical centers,” Proc. SPIE 1654, 148 (1992). 10.1117/12.60318 [DOI] [Google Scholar]

[r236] 236.Behlen F. M., et al. , “User interface optimization in a radiography display console,” Proc. SPIE 1654, 432 (1992). 10.1117/12.60297 [DOI] [Google Scholar]

[r237] 237.Horii S. C., et al. , “Comparison of case retrieval times: film versus PACS,” Proc. SPIE 1654, 236 (1992). 10.1117/12.60275 [DOI] [PubMed] [Google Scholar]

[r238] 238.Dwyer S. J., III, et al. , “Dial-up switched 56,000 bits-per-second teleradiology system,” Proc. SPIE 1654, 97 (1992). 10.1117/12.60263 [DOI] [Google Scholar]

[r239] 239.Cox J. R., Jr., et al. , “Demonstration of medical communications based on an ATM broadband network technology,” Proc. SPIE 1654, 44 (1992). 10.1117/12.60258 [DOI] [Google Scholar]

[r240] 240.Stewart B. K., et al. , “Design of a high-speed high-resolution teleradiology system,” Proc. SPIE 1654, 66 (1992). 10.1117/12.60260 [DOI] [PubMed] [Google Scholar]

[r241] 241.Mun S. K., et al. , “Command-wide teleradiology for US Armed Forces in Korea,” Proc. SPIE 1654, 81 (1992). 10.1117/12.60261 [DOI] [Google Scholar]

[r242] 242.Blaine G. J., et al. , “Teleradiology support via a narrow band ISDN and the JPEG still image compression standard,” Proc. SPIE 1654, 545 (1992). 10.1117/12.60311 [DOI] [Google Scholar]

[r243] 243.Taira R. K., et al. , “Design of a PACS cluster controller,” Proc. SPIE 1654, 203 (1992). 10.1117/12.60270 [DOI] [Google Scholar]

[r244] 244.Ratib O. M., et al. , “Distributed architecture for image archival in a hospital-wide PACS,” Proc. SPIE 1654, 222 (1992). 10.1117/12.60273 [DOI] [Google Scholar]

[r245] 245.Breant C. M., et al. , “Issues and solutions for interfacing a PACS database with a RIS,” Proc. SPIE 1654, 255 (1992). 10.1117/12.60277 [DOI] [Google Scholar]

[r246] 246.Ottes F. P., et al. , “Prototyping a PACS-RIS/HIS interface in Europe,” Proc. SPIE 1654, 551 (1992). 10.1117/12.60312 [DOI] [Google Scholar]

[r247] 247.Best D. E., et al. , “Update of the ACR-NEMA digital imaging and communications in medicine standard,” Proc. SPIE 1654, 356 (1992). 10.1117/12.60322 [DOI] [Google Scholar]

[r248] 248.Bakker A. R., “Data protection and security issues of PACS,” Proc. SPIE 1654, 509 (1992). 10.1117/12.60306 [DOI] [Google Scholar]

[r249] 249.Huda W., et al. , “Network-bandwidth and archive-storage requirements model for PACS,” Proc. SPIE 1899, 14 (1993). 10.1117/12.152885 [DOI] [Google Scholar]

[r250] 250.McNeill K. M., et al. , “Experimental high-speed network,” Proc. SPIE 1899, 271 (1993). 10.1117/12.152891 [DOI] [Google Scholar]

[r251] 251.Chen Y. P., Kim Y., “Cost-effective data storage/archival subsystem for functional PACS,” Proc. SPIE 1899, 131 (1993). 10.1117/12.152876 [DOI] [Google Scholar]

[r252] 252.Wong A. W. K., Lou S. A., Huang H. K., “PAC subsystems performance: centralized versus distributive,” Proc. SPIE 1899, 24 (1993). 10.1117/12.152894 [DOI] [Google Scholar]

[r253] 253.Andriole K. P., Ratib O. M., Huang H. K., “Picture archiving and communication system-to-personal computer radiologist workstation,” Proc. SPIE 1899, 90 (1993). 10.1117/12.152869 [DOI] [Google Scholar]

[r254] 254.Lou S. A., et al. , “2K radiological image display station,” Proc. SPIE 1899, 95 (1993). 10.1117/12.152870 [DOI] [Google Scholar]

[r255] 255.Honeyman J. C., et al. , “Functional requirements for diagnostic workstations,” Proc. SPIE 1899, 103 (1993). 10.1117/12.152871 [DOI] [Google Scholar]

[r256] 256.Keen J., Bryan S., Weatherburn G. C., “Evaluation of PACS at Hammersmith Hospital: instrument for the assessment of the subjective views of clinical staff,” Proc. SPIE 1899, 463 (1993). 10.1117/12.152917 [DOI] [Google Scholar]

[r257] 257.Mattheus R. A., “European standardization effort: interworking the goal,” Proc. SPIE 1899, 194 (1993). 10.1117/12.152883 [DOI] [Google Scholar]

[r258] 258.Fritz S. L., Roys S. R., Munjal S., “Object-oriented ACR-NEMA data dictionary in C++,” Proc. SPIE 1899, 206 (1993). 10.1117/12.152884 [DOI] [Google Scholar]

[r259] 259.Chimiak W. J., Williams R. C., “Translation of modality database entries to an ACR-NEMA transfer syntax,” Proc. SPIE 1899, 212 (1993). 10.1117/12.152886 [DOI] [Google Scholar]

[r260] 260.Honeyman J. C., et al. , “Nuclear medicine PACS with an interfile/ACR-NEMA interface and on-line medical record interface,” Proc. SPIE 1899, 408 (1993). 10.1117/12.152909 [DOI] [Google Scholar]

[r261] 261.More S. M., Blaine G. J., Jost R. G., “Performance observations based on a subset of the DICOM 3.0 draft-standard,” Proc. SPIE 1899, 218 (1993). 10.1117/12.152887 [DOI] [Google Scholar]

[r262] 262.Jost R. G., “DICOM Version 3.0 demonstration at InfoRAD 1992,” Proc. SPIE 1899, 233 (1993). 10.1117/12.152862 [DOI] [Google Scholar]

[r263] 263.Ottes F. P., et al. , “Functional specification of the HIPIN HIS/RIS-PACS interface,” Proc. SPIE 1899, 63 (1993). 10.1117/12.152860 [DOI] [Google Scholar]

[r264] 264.Bartsch F. R., Gerneth M., Schosser R., “Videoconference for radiological expert consultation in the EC-project TELEMED,” Proc. SPIE 1899, 278 (1993). 10.1117/12.152892 [DOI] [Google Scholar]

[r265] 265.Ligier Y., et al. , “Interactive software for cooperative medicine and remote consultations,” Proc. SPIE 1899, 318 (1993). 10.1117/12.152897 [DOI] [Google Scholar]

[r266] 266.Willis C. E., et al. , “Evolution of teleradiology in the defense medical establishment,” Proc. SPIE 1899, 366 (1993). 10.1117/12.152903 [DOI] [Google Scholar]

[r267] 267.Stewart B. K., et al. , “Technical development of shared-radiology educational resources via teleconferencing,” Proc. SPIE 1899, 284 (1993). 10.1117/12.152893 [DOI] [PubMed] [Google Scholar]

[r268] 268.Whitman R. A., et al. , “Performance of a teleradiology medical doctor’s workstation supported by narrow-band integrated services digital networking,” Proc. SPIE 2165, 262 (1994). 10.1117/12.174310 [DOI] [Google Scholar]

[r269] 269.Yu Y. P., et al. , “Analysis of joint photographic expert group (JPEG) compression on communications in a telepathology system,” Proc. SPIE 2165, 283 (1994). 10.1117/12.174313 [DOI] [Google Scholar]

[r270] 270.Leckie R. G., et al. , “Clinical experience with teleradiology in the US military,” Proc. SPIE 2165, 301 (1994). 10.1117/12.174315 [DOI] [Google Scholar]

[r271] 271.Bannerjee S., Kabuka M. R., “ATM-based fiber optic network for scalable and modular PACS design,” Proc. SPIE 2165, 218 (1994). 10.1117/12.174305 [DOI] [Google Scholar]

[r272] 272.Frost M. M., et al. , “Medical information metropolitan area network,” Proc. SPIE 2165, 228 (1994). 10.1117/12.174306 [DOI] [Google Scholar]

[r273] 273.Chen D. T., et al. , “Image flow management in a PACS network,” Proc. SPIE 2165, 233 (1994). 10.1117/12.174307 [DOI] [Google Scholar]

[r274] 274.Yin L., et al. , “Use of personal computer technology in supporting a radiological review workstation,” Proc. SPIE 2165, 27 (1994). 10.1117/12.174323 [DOI] [Google Scholar]

[r275] 275.Nishihara E., et al. , “Radiology information system/picture archiving and communication system architecture to assist daily practical reading at the Toshiba Hospital,” Proc. SPIE 2165, 172 (1994). 10.1117/12.174299 [DOI] [Google Scholar]

[r276] 276.Honeyman-Buck J. C., Frost M. M., Staab E. V., “On-line medical record/RIS/PACS interface,” Proc. SPIE 2165, 172 (1994). 10.1117/12.174299 [DOI] [Google Scholar]

[r277] 277.Kondoh H., et al. , “HIS-RIS-Modality-PACS integration in Osaka University,” Proc. SPIE 2165, 790 (1994). 10.1117/12.174373 [DOI] [Google Scholar]

[r278] 278.Coumans K. O., Davenport K. G., “Implementation of a stand-alone optical archive: the benefits of PACS without the problems,” Proc. SPIE 2165, 78 (1994). 10.1117/12.174375 [DOI] [Google Scholar]

[r279] 279.Wong A. W. K., et al. , “Automated prefetch mechanism: design and implementation for a radiology PACS,” Proc. SPIE 2165, 102 (1994). 10.1117/12.174293 [DOI] [Google Scholar]

[r280] 280.Wilson D. L., Smith D. V., Rice B., “Intelligent prefetch strategies for historical images in a large PACS,” Proc. SPIE 2165, 112 (1994). 10.1117/12.174294 [DOI] [Google Scholar]

[r281] 281.Sheng O. R. L., et al. , “Knowledge-based image retrieval: a new generation design,” Proc. SPIE 2165, 137 (1994). 10.1117/12.174296 [DOI] [Google Scholar]

[r282] 282.Prior F. W., et al. , “DICOM user conformance profile: proof of concept,” Proc. SPIE 2165, 348 (1994). 10.1117/12.174320 [DOI] [Google Scholar]

[r283] 283.Moore S. M., et al. , “Measured performance of DICOM-TCP and DICOM-ISO implementations,” Proc. SPIE 2165, 359 (1994). 10.1117/12.174321 [DOI] [Google Scholar]

[r284] 284.Jensch P. F., et al. , “DICOM v3.0 – THE CEN trial implementation,” Proc. SPIE 2165, 368 (1994). 10.1117/12.174322 [DOI] [Google Scholar]

[r285] 285.Kuzmak P. M., Dayhoff R. E., “Bidirectional ACR-NEMA interface between the VA’s DHCP integrated imaging system and the Siemens-Loral PACS,” Proc. SPIE 2165, 387 (1994). 10.1117/12.174325 [DOI] [PMC free article] [PubMed] [Google Scholar]

[r286] 286.Lee J. K., et al. , “Adaptation of industry standards to PACS,” Proc. SPIE 2165, 397 (1994). 10.1117/12.174326 [DOI] [Google Scholar]

[r287] 287.Frost M. M., Honeyman-Buck J. C., Staab E. V., “DICOM server for computed tomography and magnetic resonance acquisition to an archive,” Proc. SPIE 2165, 70 (1994). 10.1117/12.174365 [DOI] [Google Scholar]

[r288] 288.Duerinckx A. J., et al. , “Evaluation and early medical experience with an ultrasound mini-PACS system at the VA Medical Center West Los Angeles,” Proc. SPIE 2165, 404 (1994). 10.1117/12.174327 [DOI] [Google Scholar]

[r289] 289.Gustafson D. E., et al. , “Scalable ultrasound PACS: evolving needs for multimode ultrasound image and data management,” Proc. SPIE 2165, 418 (1994). 10.1117/12.174328 [DOI] [Google Scholar]

[r290] 290.Georgiou M. F., et al. , “Multivendor nuclear medicine pacs provide fully digital clinical operation at the University of Miami Jackson Memorial Hospital,” Proc. SPIE 2165, 429 (1994). 10.1117/12.174329 [DOI] [Google Scholar]

[r291] 291.Wilson A. J., et al. , “Digitization and remote transmission of magnetic resonance hard-copy images: a clinical comparison of original and soft-copy images,” Proc. SPIE 2165, 438 (1994). 10.1117/12.174330 [DOI] [Google Scholar]

[r292] 292.van Gennip E. M. S. K., et al. , “TEASS: evaluation of PACS in three European hospitals: first results and recommendations,” Proc. SPIE 2165, 501 (1994). 10.1117/12.174339 [DOI] [Google Scholar]

[r293] 293.Hangiandreou N. J., et al. , “Current status of the joint Mayo Clinic-IBM PACS project,” Proc. SPIE 2165, 519 (1994). 10.1117/12.174341 [DOI] [Google Scholar]

[r294] 294.Huang H. K., et al. , “Second generation picture archiving and communication system,” Proc. SPIE 2165, 527 (1994). 10.1117/12.174342 [DOI] [Google Scholar]

[r295] 295.Smith D. V., et al. , “Lessons learned and two years clinical experience in implementing the medical diagnostic imaging support (MDIS) system at Madigan Army Medical Center,” Proc. SPIE 2165, 538 (1994). 10.1117/12.174343 [DOI] [Google Scholar]

[r296] 296.Langlotz C. P., et al. , “Methodology for the economic assessment of PACS,” Proc. SPIE 2165, 584 (1994). 10.1117/12.174348 [DOI] [Google Scholar]

[r297] 297.Bryan S., et al. , “Technology assessment of PACS: measurement and analysis of radiologists’ reporting times when reporting from film,” Proc. SPIE 2165, 820 (1994). 10.1117/12.174378 [DOI] [Google Scholar]

[r298] 298.Glicksman R. A., Prior F. W., “Image quality concepts for PACS,” Proc. SPIE 2165, 694 (1994). 10.1117/12.174360 [DOI] [Google Scholar]

[r299] 299.Romlein J. R., et al. , “Transitioning process of a film-based radiology department to direct digital imaging,” Proc. SPIE 2165, 850 (1994). 10.1117/12.174382 [DOI] [Google Scholar]

[r300] 300.Fritz S. L., et al. , “Implementing a DICOM-HL7 interface application,” Proc. SPIE 2435, 100 (1995). 10.1117/12.208764 [DOI] [Google Scholar]

[r301] 301.Beaver S. M., Sippel-Schmidt T. M., “Approach to implementing a DICOM network: incorporate both economics and workflow adaptation,” Proc. SPIE 2435, 124 (1995). 10.1117/12.208767 [DOI] [Google Scholar]

[r302] 302.Reynolds R. A., et al. , “Matching Images from digital modalities to exams scheduled via RIS or PACS,” Proc. SPIE 2435, 340 (1995). 10.1117/12.208794 [DOI] [Google Scholar]

[r303] 303.Kuzmak P. M., Norton G. S., Dayhoff R. E., “Using experience with bidirectional HL7-ACR-NEMA interfaces between the Federal Government HIS/RIS and commercial PACS to plan for DICOM,” Proc. SPIE 2435, 132 (1995). 10.1117/12.208798 [DOI] [Google Scholar]

[r304] 304.Meissner M. C., Levine B. A., Mun S. K., “RIS/HIS and PACS interfaces: evaluating the use of standards,” Proc. SPIE 2435, 462 (1995). 10.1117/12.208810 [DOI] [Google Scholar]

[r305] 305.Fritz S. L., et al. , “C++ class library for DICOM services to support a HIS/RIS interface,” Proc. SPIE 2435, 462 (1995). 10.1117/12.208810 [DOI] [Google Scholar]

[r306] 306.Huang H. K., et al. , “High-performance testbed network with ATM technology for neuroimaging,” Proc. SPIE 2435, 146 (1995). 10.1117/12.208768 [DOI] [Google Scholar]

[r307] 307.Tohme W. G., et al. , “Evaluating the role of gigabit speed wide-area networks in remote medical treatment,” Proc. SPIE 2435, 166 (1995). 10.1117/12.208770 [DOI] [Google Scholar]

[r308] 308.Lou S. A., et al. , “Interhospital CT image communication: T-1 line versus courier service,” Proc. SPIE 2435, 188 (1995). 10.1117/12.208773 [DOI] [Google Scholar]

[r309] 309.Stewart B. K., Carter S. J., Rowberg A. H., “Application of the advanced communications technology satellite for teleradiology and telemedicine,” Proc. SPIE 2435, 210 (1995). 10.1117/12.208776 [DOI] [PMC free article] [PubMed] [Google Scholar]

[r310] 310.Kim Y., et al. , “Seahawk: telemedicine project in the Pacific Northwest,” Proc. SPIE 2435, 232 (1995). 10.1117/12.208778 [DOI] [Google Scholar]

[r311] 311.Morin R. L., Berquist T. H., Pietan J. H., “Clinically oriented evaluation of family practice teleradiology,” Proc. SPIE 2435, 239 (1995). 10.1117/12.208779 [DOI] [Google Scholar]

[r312] 312.Tohme W. G., et al. , “Project RavenCare: global multimedia telemedicine in Alaska,” Proc. SPIE 2435, 519 (1995). 10.1117/12.208817 [DOI] [Google Scholar]

[r313] 313.Shile P. E., Friedland J. A., Wilson A. J., “Radiologists’ acceptance of teleradiology: responses to surveys in 1990 and 1994,” Proc. SPIE 2435, 196 (1995). 10.1117/12.208774 [DOI] [Google Scholar]

[r314] 314.Horii S. C., et al. , “Use of mini-PACS technology in ultrasound: the potential for productivity improvement,” Proc. SPIE 2435, 257 (1995). 10.1117/12.208783 [DOI] [Google Scholar]

[r315] 315.Dwyer S. J., III, et al. , “Evaluation of a PACS for CT and MR: film compared to PACS,” Proc. SPIE 2435, 268 (1995). 10.1117/12.208785 [DOI] [Google Scholar]

[r316] 316.Lindhardt F. E., “PACS – The Viborg project: clinical experiences with a totally digitalized hospital,” Proc. SPIE 2435, 312 (1995). 10.1117/12.208790 [DOI] [Google Scholar]

[r317] 317.Mosser H. M., Paertan G., Hruby W., “Clinical routine operation of a filmless radiology department: three years experience,” Proc. SPIE 2435, 321 (1995). 10.1117/12.208791 [DOI] [Google Scholar]

[r318] 318.Wong A. W. K., Huang H. K., Arenson R. L., “Hierarchical image storage management: design and implementation for a distributed PACS,” Proc. SPIE 2435, 61 (1995). 10.1117/12.208826 [DOI] [Google Scholar]

[r319] 319.He Y., et al. , “Fault tolerance techniques to assure data integrity in high-volume PACS image archives,” Proc. SPIE 2435, 378 (1995). 10.1117/12.208799 [DOI] [Google Scholar]

[r320] 320.Behlen F. M., Hoffman K. R., MacMahon Heber, “Long-term strategies for PACS archive design,” Proc. SPIE 2711, 2 (1996). 10.1117/12.239233 [DOI] [Google Scholar]

[r321] 321.Frost M. M., Honeyman-Buck J. C., Staab E. V., “PACS Archive strategy utilizing a 3TB Jukebox,” Proc. SPIE 2711, 22 (1996). 10.1117/12.239264 [DOI] [Google Scholar]

[r322] 322.Van M. D., Humphrey L. M., Ravin C. E., “Development of a high-performance image server Using ATM-technology,” Proc. SPIE 2711, 9 (1996). 10.1117/12.239242 [DOI] [Google Scholar]

[r323] 323.Lee J. K., et al. , “ATM-distributed PACS server for ICU application,” Proc. SPIE 2711, 14 (1996). 10.1117/12.239253 [DOI] [Google Scholar]

[r324] 324.Duerinckx A. J., et al. , “Assessment of asynchronous transfer mode (ATM) networks for regional teleradiology,” Proc. SPIE 2711, 61 (1996). 10.1117/12.239298 [DOI] [Google Scholar]

[r325] 325.Steward B. K., et al. , “Real-time compressed video ultrasound using the advanced communications technology satellite,” Proc. SPIE 2711, 194 (1996). 10.1117/12.239248 [DOI] [PMC free article] [PubMed] [Google Scholar]

[r326] 326.Gnoyke H., “Standards for the integration of modalities with information systems and IMAC systems based on DICOM/MEDICOM supplements,” Proc. SPIE 2711, 72 (1996). 10.1117/12.239234 [DOI] [Google Scholar]

[r327] 327.Chimiak W. J., “Preliminary DICOM acceptance testing using the central test node,” Proc. SPIE 2711, 82 (1996). 10.1117/12.239235 [DOI] [Google Scholar]

[r328] 328.Moore S. M., “Observations on DICOM demonstrations at the RSNA annual meetings,” Proc. SPIE 2711, 89 (1996). 10.1117/12.239236 [DOI] [Google Scholar]

[r329] 329.Grevera G. J., Feingold E. R., Horii S. C., “WWW to DICOM interface,” Proc. SPIE 2711, 109 (1996). 10.1117/12.239238 [DOI] [Google Scholar]

[r330] 330.Honeyman-Buck J. C., et al. , “RIS requirements to support a PACS infrastructure,” Proc. SPIE 2711, 120 (1996). 10.1117/12.239239 [DOI] [Google Scholar]

[r331] 331.Enning C. J. W. A., et al. , “Evaluation of a multimedia information system for endoscopy,” Proc. SPIE 2711, 205 (1996). 10.1117/12.239249 [DOI] [Google Scholar]

[r332] 332.van Poppel B. M., et al. , “Endoscopy PACS integrated with the HIS,” Proc. SPIE 2711, 483 (1996). 10.1117/12.239283 [DOI] [Google Scholar]

[r333] 333.Lobodzzinski S. S., Maurer H., “Hypermedia network architecture for digital echocardiography,” Proc. SPIE 2711, 214 (1996). 10.1117/12.239250 [DOI] [Google Scholar]

[r334] 334.Barnett B. G., et al. , “Satellite teleradiology test bed for digital mammography,” Proc. SPIE 2711, 308 (1996). 10.1117/12.239263 [DOI] [Google Scholar]

[r335] 335.So G. J., et al. , “First international telemedicine trial to China using the internet,” Proc. SPIE 2711, 327 (1996). 10.1117/12.239266 [DOI] [Google Scholar]

[r336] 336.Huang H. K., et al. , “Current status of the UCSF second-generation PACS,” Proc. SPIE 2711, 364 (1996). 10.1117/12.239270 [DOI] [Google Scholar]

[r337] 337.Morin R. L., Berquist T. H., Rueger W., “Mayo Clinic Jacksonville electronic radiology practice,” Proc. SPIE 2711, 384 (1996). 10.1117/12.239272 [DOI] [Google Scholar]

[r338] 338.Toshimitsu A., et al. , “Toshiba General Hospital PACS for routine in- and outpatient clinics,” Proc. SPIE 2711, 466 (1996). 10.1117/12.239281 [DOI] [Google Scholar]

[r339] 339.Jeromin L. S., et al. , “Productivity improvements with a direct digital radiography system integrated with PACS,” Proc. SPIE 2711, 236 (1996). 10.1117/12.239255 [DOI] [Google Scholar]

[r340] 340.Melson D. L., et al. , “Methodology for cost analysis of film-based and filmless portable chest systems,” Proc. SPIE 2711, 400 (1996). 10.1117/12.239273 [DOI] [Google Scholar]

[r341] 341.Andriole K. P., et al. , “Clinical comparison of CR and screen film for imaging the critically Ill neonate,” Proc. SPIE 2711, 281 (1996). 10.1117/12.239259 [DOI] [Google Scholar]

[r342] 342.Andriole K. P., et al. , “Impact and utilization studies of a PACS display station in an ICU setting,” Proc. SPIE 2711, 286 (1996). 10.1117/12.239260 [DOI] [Google Scholar]

[r343] 343.Horii S. C., et al. , “PACS workstation functions: usage differences between radiologists and MICU physicians,” Proc. SPIE 2711, 266 (1996). 10.1117/12.239257 [DOI] [Google Scholar]

[r344] 344.Huang H. K., Lou S. A., Wong A. W. K., “PACS pitfalls and bottlenecks,” Proc. SPIE 3035, 2 (1997). 10.1117/12.274553 [DOI] [Google Scholar]

[r345] 345.Horii S. C., et al. , “What do we need to advance PACS workstations: a critical review with suggestions,” Proc. SPIE 3035, 6 (1997). 10.1117/12.274562 [DOI] [Google Scholar]

[r346] 346.Kim J. H., et al. , “HIS/RIS/pacs integration toward total hospital information system,” Proc. SPIE 3035, 20 (1997). 10.1117/12.274583 [DOI] [Google Scholar]

[r347] 347.Alsafadi Y. H., Lord W. P., Mankovich N. H., “Enterprise communication framework as a means to PACS/information systems interoperability,” Proc. SPIE 3035, 29 (1997). 10.1117/12.274592 [DOI] [PubMed] [Google Scholar]

[r348] 348.Siegel E. L., et al. , “Analysis of the clinical impact of a DICOM HIS/RIS to modality interface and recommendations for improvement,” Proc. SPIE 3035, 146 (1997). 10.1117/12.274564 [DOI] [Google Scholar]

[r349] 349.Kuzmak P. M., Dayhoff R. E., “Experience with MUMPS-based DICOM interfaces between the department of veterans affairs HIS/RIS and commercial vendors,” Proc. SPIE 3035, 134 (1997). 10.1117/12.274563 [DOI] [Google Scholar]

[r350] 350.Wong A. W. K., Huang H. K., Arenson R. L., “Adaptation of DICOM to an operational PACS,” Proc. SPIE 3035, 153 (1997). 10.1117/12.274566 [DOI] [Google Scholar]

[r351] 351.Behlen F. M., et al. , “Radiology information system control of a DICOM-based PACS,” Proc. SPIE 3035, 159 (1997). 10.1117/12.274567 [DOI] [Google Scholar]

[r352] 352.Clunie D. A., “Progress in extending DICOM to media interchange,” Proc. SPIE 3035, 495 (1997). 10.1117/12.274606 [DOI] [Google Scholar]

[r353] 353.Feingold E. R., et al. , “Web-based radiology applications for clinicians and radiologists,” Proc. SPIE 3035, 60 (1997). 10.1117/12.274630 [DOI] [Google Scholar]

[r354] 354.Przybylowicz J. E., “Enterprise imaging and display consistency,” Proc. SPIE 3035, 595 (1997). 10.1117/12.274622 [DOI] [Google Scholar]

[r355] 355.Hayrapetian A. S., et al. , “Workstation and network needs for very large PACS implementation,” Proc. SPIE 3035, 291 (1997). 10.1117/12.274610 [DOI] [Google Scholar]

[r356] 356.Dai H. L., et al. , “Breaking the bottleneck: high-speed medical image transmission through ATM network: implementation and application,” Proc. SPIE 3035, 108 (1997). 10.1117/12.274558 [DOI] [Google Scholar]

[r357] 357.Whitman R. A., et al. , “Management of ATM-based networks supporting multimedia medical information systems,” Proc. SPIE 3035, 113 (1997). 10.1117/12.274559 [DOI] [Google Scholar]

[r358] 358.Siegel E. L., et al. , “Three and a half years’ experience with PACS at the Baltimore VA Medical Center,” Proc. SPIE 3035, 15 (1997). 10.1117/12.274573 [DOI] [Google Scholar]

[r359] 359.Duerinckx A. J., et al. , “Teleradiology for Veterans Integrated Service Networks,” Proc. SPIE 3035, 124 (1997). 10.1117/12.274561 [DOI] [Google Scholar]

[r360] 360.Cleary K. R., et al. , “Teleradiology network to improve patient care in a peacekeeping military operation,” Proc. SPIE 3035, 222 (1997). 10.1117/12.274575 [DOI] [Google Scholar]

[r361] 361.Kim J. H., et al. , “Development of hospital-integrated large-scale PACS in Seoul National University Hospital,” Proc. SPIE 3035, 248 (1997). 10.1117/12.274578 [DOI] [Google Scholar]

[r362] 362.Wilson D. L., “Filmless radiology at Brooke Army Medical Center,” Proc. SPIE 3035, 256 (1997). 10.1117/12.274579 [DOI] [Google Scholar]

[r363] 363.Krupinski E. A., Hopper L., “Teleradiology in rural Arizona: user’s perspective,” Proc. SPIE 3035, 350 (1997). 10.1117/12.274590 [DOI] [Google Scholar]

[r364] 364.Hu D., et al. , “Engineering and clinical-oriented solution to cost-effective PACS for developing areas in China,” Proc. SPIE 3035, 552 (1997). 10.1117/12.274615 [DOI] [Google Scholar]

[r365] 365.Behlen F. M., et al. , “Multiresolution storage in a PACS archive,” Proc. SPIE 3035, 39 (1997). 10.1117/12.274601 [DOI] [Google Scholar]

[r366] 366.Chunn T., “Archival storage solutions for PACS,” Proc. SPIE 3035, 47 (1997). 10.1117/12.274620 [DOI] [Google Scholar]

[r367] 367.Collmann J. R., et al. , “Comparing the security risks of paper-based and computerized patient record systems,” Proc. SPIE 3035, 172 (1997). 10.1117/12.274569 [DOI] [Google Scholar]

[r368] 368.Meissner M. C., et al. , “Protecting clinical data in PACS, teleradiology systems and research environments,” Proc. SPIE 3035, 183 (1997). 10.1117/12.274570 [DOI] [Google Scholar]

[r369] 369.Thiel A., et al. , “Telemedicine with integrated data security in ARM-based networks,” Proc. SPIE 3035, 191 (1997). 10.1117/12.274571 [DOI] [Google Scholar]

[r370] 370.Zhang J., Andriole K. P., Huang H. K., “Computed radiographic image postprocessing in picture archiving and communication systems,” Proc. SPIE 3035, 310 (1997). 10.1117/12.274585 [DOI] [Google Scholar]

[r371] 371.Andriole K. P., Gould R. G., Arenson R. L., “Computed radiography in an emergency department setting,” Proc. SPIE 3035, 389 (1997). 10.1117/12.274595 [DOI] [Google Scholar]

[r372] 372.Reiker G. G., et al. , “Filmless digital chest radiography within the radiology department,” Proc. SPIE 3035, 355 (1997). 10.1117/12.274591 [DOI] [Google Scholar]

[r373] 373.Lou S. A., et al. , “Full-field direct digital telemammography: preliminary,” Proc. SPIE 3035, 369 (1997). 10.1117/12.274593 [DOI] [PubMed] [Google Scholar]

[r374] 374.Dostalova T., Smutny V., “Dental archives based on images,” Proc. SPIE 3035, 464 (1997). 10.1117/12.274602 [DOI] [Google Scholar]

[r375] 375.Pratt H. M., et al. , “Incremental cost of a department-wide PACS/CR implementation,” Proc. SPIE 3035, 413 (1997). 10.1117/12.274598 [DOI] [Google Scholar]

[r376] 376.Reiner B. I., et al. , “Impact of filmless operation on staff productivity in the CT Department,” Proc. SPIE 3035, 431 (1997). 10.1117/12.274600 [DOI] [Google Scholar]

[r377] 377.Wreder K., Nararro E., “PACS as an element of the computerized patient record: a health care enterprise model,” Proc. SPIE 3035, 445 (1997). 10.1117/12.274628 [DOI] [Google Scholar]

[r378] 378.Chacko A. K., Lollar H. W., “Proposal for an information revolution in imaging in healthcare: the dawn of the new millenium,” Proc. SPIE 3035, 455 (1997). 10.1117/12.274629 [DOI] [Google Scholar]

[r379] 379.Chimiak W. J., Boehme J. M., “Fault tolerant high-performance PACS network design and implementation,” Proc. SPIE 3339, 2 (1998). 10.1117/12.319758 [DOI] [Google Scholar]

[r380] 380.Blume H. R., et al. , “Scalability, performance and fault tolerance of PACS architectures,” Proc. SPIE 3339, 112 (1998). 10.1117/12.319760 [DOI] [Google Scholar]

[r381] 381.Komo D., et al. , “DICOM implementation on online tape library storage system,” Proc. SPIE 3339, 105 (1998). 10.1117/12.319759 [DOI] [Google Scholar]

[r382] 382.Thiel A., et al. , “Security concepts in clinical applications using DICOM,” Proc. SPIE 3339, 11 (1998). 10.1117/12.319767 [DOI] [Google Scholar]

[r383] 383.Daniell A. L., Jin M. Y., Valentino D. J., “Clinical evaluation of high-performance lossless image compression,” Proc. SPIE 3339, 39 (1998). 10.1117/12.319798 [DOI] [Google Scholar]

[r384] 384.Horii S. C., et al. , “Prototype controls for a plain radiography workstation,” Proc. SPIE 3339, 87 (1998). 10.1117/12.319822 [DOI] [Google Scholar]

[r385] 385.Zhang J., et al. , “Real-time teleconsultation with high-resolution and large-volume medical imaging,” Proc. SPIE 3339, 185 (1998). 10.1117/12.319768 [DOI] [PubMed] [Google Scholar]

[r386] 386.Telepak R. J., et al. , “Five years’ experience in a (really) rural teleradiology practice: was it worth it? The successes and failures,” Proc. SPIE 3339, 192 (1998). 10.1117/12.319769 [DOI] [Google Scholar]

[r387] 387.Chacko A. K., et al. , “Vision and benefits of a virtual radiology environment for the US Army,” Proc. SPIE 3339, 200 (1998). 10.1117/12.319770 [DOI] [Google Scholar]

[r388] 388.Duerinckx A. J., et al. , “First six months of clinical usage of an ATM network link between two Veterans Affairs Medical Centers,” Proc. SPIE 3339, 226 (1998). 10.1117/12.319773 [DOI] [Google Scholar]

[r389] 389.Siegel E. L., Reiner B. I., Protopapas Z., “Evaluation of PACS in a multihospital environment,” Proc. SPIE 3339, 226 (1998). 10.1117/12.319773 [DOI] [Google Scholar]

[r390] 390.Smith E. M., et al. , “Project MICAS: a multivendor open-system incremental approach to implementing an integrated enterprise-wide PACS: works in progress,” Proc. SPIE 3339, 457 (1998). 10.1117/12.319801 [DOI] [Google Scholar]

[r391] 391.Erickson B. J., et al. , “Clinician image review patterns in an outpatient setting,” Proc. SPIE 3339, 406 (1998). 10.1117/12.319794 [DOI] [Google Scholar]

[r392] 392.Langer S. G., Stewart B. K., “Implementation of an HL7/DICOM broker for automated patient demographic data entry in computed radiography systems,” Proc. SPIE 3339, 556 (1998). 10.1117/12.319815 [DOI] [Google Scholar]

[r393] 393.Melson D. L., et al. , “Impact of a voice recognition system on report cycle time and radiologist reading time,” Proc. SPIE 3339, 226 (1998). 10.1117/12.319773 [DOI] [Google Scholar]

[r394] 394.Strickland N. H., et al. , “Implementation of a major hardware and software upgrade in a hospital-wide PACS during clinical use,” Proc. SPIE 3339, 496 (1998). 10.1117/12.319806 [DOI] [Google Scholar]

[r395] 395.Thiel A., et al. , “Security extensions to DICOM,” Proc. SPIE 3662, 72 (1999). 10.1117/12.352780 [DOI] [Google Scholar]

[r396] 396.Zhou X., Lou S. A., Huang H. K., “Authenticity and integrity of digital mammographic images,” Proc. SPIE 3662, 138 (1999). 10.1117/12.352736 [DOI] [Google Scholar]

[r397] 397.DeJarnette W. T., et al. , “Standards-based distributed PACS architecture,” Proc. SPIE 3662, 37 (1999). 10.1117/12.352764 [DOI] [Google Scholar]

[r398] 398.Stewart B. K., Langer S. G., Martin K. P., “Integration of multiple DICOM web servers into an enterprise-wide web-based electronic medical record,” Proc. SPIE 3662, 52 (1999). 10.1117/12.352772 [DOI] [Google Scholar]

[r399] 399.Clunie D. A., “Designing and implementing a PACS-aware DICOM image object for digital x-ray, mammography and intraoral applications,” Proc. SPIE 3662, 83 (1999). 10.1117/12.352730 [DOI] [Google Scholar]

[r400] 400.Romlein J. R., et al. , “PACS: acceptance test, quality control, warranty, and maintenance continuum,” Proc. SPIE 3662, 111 (1999). 10.1117/12.352733 [DOI] [Google Scholar]

[r401] 401.Siegel E. L., Reiner B. I., Cadogan M., “Frequency and failure of high-resolution monitors in a filmless imaging department,” Proc. SPIE 3662, 248 (1999). 10.1117/12.352751 [DOI] [PMC free article] [PubMed] [Google Scholar]

[r402] 402.McNeill K. M., Holcomb M. J., Ovitt T. W., “Integrating LAN/WAN technologies in support of multimedia telemedicine and teleradiology,” Proc. SPIE 3662, 156 (1999). 10.1117/12.352738 [DOI] [Google Scholar]

[r403] 403.Wong A. W. K., Huang H. K., “High-performance image storage and communications with fiber channel technology for PACS,” Proc. SPIE 3662, 163 (1999). 10.1117/12.352740 [DOI] [Google Scholar]

[r404] 404.Honeyman-Buck J. C., Frost M. M., Drane W. E., “Expanding the PACS archive to support clinical review, research and education missions,” Proc. SPIE 3662, 171 (1999). 10.1117/12.352741 [DOI] [Google Scholar]

[r405] 405.Persons K. R., et al. , “JPEG/wavelet ultrasound compression study,” Proc. SPIE 3662, 232 (1999). 10.1117/12.352750 [DOI] [Google Scholar]

[r406] 406.Huang H. K., et al. , “Digital hand atlas for bone age assessment of children: an application of PACS database,” Proc. SPIE 3662, 178 (1999). 10.1117/12.352742 [DOI] [Google Scholar]

[r407] 407.Andriole K. P., et al. , “CR softcopy display presets based on optimum visualization of specific findings,” Proc. SPIE 3662, 264 (1999). 10.1117/12.352753 [DOI] [Google Scholar]

[r408] 408.Zhang J., et al. , “CR image background removal: a collection of interesting cases,” Proc. SPIE 3662, 377 (1999). 10.1117/12.352769 [DOI] [Google Scholar]

[r409] 409.Gitlin J. N., Drinkard M., “CCD versus laser: a comparative study of two types of X-ray film digitizers,” Proc. SPIE 3662, 438 (1999). 10.1117/12.352778 [DOI] [Google Scholar]

[r410] 410.Reiner B. I., Siegel E. L., Rostenberg B., “Redesigning the PACS reading room: optimizing monitor and room lighting,” Proc. SPIE 3662, 276 (1999). 10.1117/12.352756 [DOI] [Google Scholar]

[r411] 411.Horii S. C., et al. , “Replacing film with PACS: work shifting and lack of automation,” Proc. SPIE 3662, 317 (1999). 10.1117/12.352761 [DOI] [Google Scholar]

[r412] 412.Dwyer S. J., III, “A personalized view of the history of PACS in the USA,” Proc. SPIE 3980, 2 (2000). 10.1117/12.386388 [DOI] [Google Scholar]

[r413] 413.Lemke H. U., et al. , “Early developments of PACS in Europe,” Proc. SPIE 3980, 12 (2000). 10.1117/12.386396 [DOI] [Google Scholar]

[r414] 414.Gell G., “PACS-Graz 1985-2000: from a scientific pilot to a state-wide multimedia radiological information system,” Proc. SPIE 3980, 19 (2000). 10.1117/12.386405 [DOI] [Google Scholar]

[r415] 415.Huang H. K., “PACS implementation experiences: from in-house to partnerships to advisory board,” Proc. SPIE 3980, 124 (2000). 10.1117/12.386394 [DOI] [Google Scholar]

[r416] 416.Siegel E. L., Reiner B. I., Kuzmak P. M., “Adoption of PACS by the Department of Veterans Affairs: the past, the present and future plans,” Proc. SPIE 3980, 134 (2000). 10.1117/12.386395 [DOI] [Google Scholar]

[r417] 417.Chacko A. K., et al. , “PACS implementation in the US Department of Defense,” Proc. SPIE 3980, 139 (2000). 10.1117/12.386397 [DOI] [Google Scholar]

[r418] 418.Channin D. S., Hawkins R. C., Enzmann D. R., “North-by-northwesters: initial experience with PACS at Northwestern Memorial Hospital,” Proc. SPIE 3980, 275 (2000). 10.1117/12.386414 [DOI] [Google Scholar]

[r419] 419.Kim H. J., et al. , “Design of a full PACS with experiences of mini-PACS in Yonsei University Medical Center,” Proc. SPIE 3980, 312 (2000). 10.1117/12.386417 [DOI] [Google Scholar]

[r420] 420.Olges N. H., et al. , “Integrating JPEG compression with DICOM: experiences and technical issues,” Proc. SPIE 3980, 46 (2000). 10.1117/12.386440 [DOI] [Google Scholar]

[r421] 421.Clunie D. A., “Lossless compression of grayscale medical images: effectiveness of traditional and state-of-the-art approaches,” Proc. SPIE 3980, 74 (2000). 10.1117/12.386389 [DOI] [Google Scholar]

[r422] 422.DH Foos, et al. , “JPEG 2000 compression of medical imagery,” Proc. SPIE 3980, 85 (2000). 10.1117/12.386390 [DOI] [Google Scholar]

[r423] 423.Andriole K. P., Hovanes M. E., Rowberg A. H., “Clinical utility of wavelet compression for resolution-enhanced chest radiography,” Proc. SPIE 3980, 107 (2000). 10.1117/12.386392 [DOI] [Google Scholar]

[r424] 424.Chen C. W., et al. , “Wavelet-based compression of pathological images for telemedicine applications,” Proc. SPIE 3980, 113 (2000). 10.1117/12.386393 [DOI] [Google Scholar]

[r425] 425.Cho Y. H., et al. , “Implementation of the test station for vendors’ equipment with DICOM 3.0,” Proc. SPIE 3980, 68 (2000). 10.1117/12.386442 [DOI] [Google Scholar]

[r426] 426.Romlein J. R., et al. , “PACS: moving a live PACS with zero downtime,” Proc. SPIE 3980, 266 (2000). 10.1117/12.386413 [DOI] [Google Scholar]

[r427] 427.Meyers J. A., “PACS: from planning to implementation for a new hospital facility,” Proc. SPIE 4323, 1 (2001). 10.1117/12.435474 [DOI] [Google Scholar]

[r428] 428.Vogl R., “Going all digital in a University Hospital: a unified large-scale PACS for multiple departments and hospitals,” Proc. SPIE 4323, 7 (2001). 10.1117/12.435481 [DOI] [Google Scholar]

[r429] 429.Chan L. W., Hartzman S., Trambert M., “Successful PACS at a community hospital,” Proc. SPIE 4323, 57 (2001). 10.1117/12.435456 [DOI] [Google Scholar]

[r430] 430.Zhang J., et al. , “Design and implementation of picture archiving and communication system in Huadong Hospital,” Proc. SPIE 4323, 73 (2001). 10.1117/12.435459 [DOI] [Google Scholar]

[r431] 431.Bao J., Gao J., “PACS development in China and the component PACS system,” Proc. SPIE 4323, 380 (2001). 10.1117/12.435504 [DOI] [Google Scholar]

[r432] 432.Andriole K. P., Luth D. M., Gould R. G., “Workflow comparison of DR and screen-film dedicated chest systems,” Proc. SPIE 4323, 203 (2001). 10.1117/12.435477 [DOI] [Google Scholar]

[r433] 433.Huda W., et al. , “Clinical performance of a prototype flat-panel digital detector for general radiography,” Proc. SPIE 4323, 397 (2001). 10.1117/12.435506 [DOI] [Google Scholar]

[r434] 434.Blume H. R., et al. , “Practical aspects of grayscale calibration of display systems,” Proc. SPIE 4323, 28 (2001). 10.1117/12.435509 [DOI] [Google Scholar]

[r435] 435.Siegel E. L., et al. , “Effect of monitor image quality on the soft-copy interpretation of chest CR images,” Proc. SPIE 4323, 42 (2001). 10.1117/12.435510 [DOI] [Google Scholar]

[r436] 436.Riesmeier J., et al. , “DICOM image display consistency: a test environment,” Proc. SPIE 4323, 47 (2001). 10.1117/12.435511 [DOI] [Google Scholar]

[r437] 437.Clunie D. A., “DICOM structured reporting: an object model as an implementation boundary,” Proc. SPIE 4323, 207 (2001). 10.1117/12.435478 [DOI] [Google Scholar]

[r438] 438.Alberts C. J., Dorofee A., “HIPAA and information security risk: implementing an enterprise-wide risk management strategy,” Proc. SPIE 4323, 97 (2001). 10.1117/12.435462 [DOI] [Google Scholar]

[r439] 439.Sostrom S., Collmann J. R., “Reviewing and reforming policy in health enterprise information security,” Proc. SPIE 4323, 118 (2001). 10.1117/12.435464 [DOI] [Google Scholar]

[r440] 440.Collmann J. R., “HIPAA and the military health system: organizing technological and organizational reform in large enterprises,” Proc. SPIE 4323, 126 (2001). 10.1117/12.435465 [DOI] [Google Scholar]

[r441] 441.Parisot C. R., et al. , “Management and presentation of grouped procedures: has the IHE integration profile cracked the toughest radiology workflow nut?” Proc. SPIE 4323, 192 (2001). 10.1117/12.435476 [DOI] [Google Scholar]

[r442] 442.Brown M. J. G., et al. , “Assessing imaging procedure results outside the imaging department: a simple well-tried format,” Proc. SPIE 4323, 278 (2001). 10.1117/12.435490 [DOI] [Google Scholar]

[r443] 443.Siegel E. L., Reiner B. I., “Clinical challenges associated with incorporation of nonradiology images into the electronic medical record,” Proc. SPIE 4323, 287 (2001). 10.1117/12.435492 [DOI] [Google Scholar]

[r444] 444.Shani U., “Maintaining a legal status for filmless archived digital medical images,” Proc. SPIE 4323, 109 (2001). 10.1117/12.435463 [DOI] [Google Scholar]

[r445] 445.Honeyman-Buck J. C., Arreola M., Frost M. M., “PACS according to Murphy: what can and will go wrong,” Proc. SPIE 4685, 7 (2002). 10.1117/12.466998 [DOI] [Google Scholar]

[r446] 446.Horii S. C., et al. , “PACS technologies and reliability: are we making things better or worse?” Proc. SPIE 4685, 16 (2002). 10.1117/12.467007 [DOI] [Google Scholar]

[r447] 447.Zhang J., et al. , “Automatic monitoring system for PACS management and operation,” Proc. SPIE 4685, 348 (2002). 10.1117/12.467026 [DOI] [Google Scholar]

[r448] 448.Kennedy R. L., Seibert J. A., “Error component analysis for PACS: operational sources of data error in real world PACS for DICOM series, study and patient level identifiers,” Proc. SPIE 4685, 206 (2002). 10.1117/12.467009 [DOI] [Google Scholar]

[r449] 449.Choi H. S., “Evolution of filmless PACS in Korea,” Proc. SPIE 4685, 42 (2002). 10.1117/12.467039 [DOI] [Google Scholar]

[r450] 450.Kim H. J., “PACS industry in Korea,” Proc. SPIE 4685, 50 (2002). 10.1117/12.467040 [DOI] [Google Scholar]

[r451] 451.Kim J. H., “Technical aspects of PACS in Korea,” Proc. SPIE 4685, 58 (2002). 10.1117/12.467041 [DOI] [Google Scholar]

[r452] 452.Lim H. W., et al. , “Full PACS installation in Seoul National University Hospital Korea,” Proc. SPIE 4685, 75 (2002). 10.1117/12.466991 [DOI] [Google Scholar]

[r453] 453.Lim J. H., “Cost justification of filmless PACS and national policy,” Proc. SPIE 4685, 72 (2002). 10.1117/12.466990 [DOI] [Google Scholar]

[r454] 454.Suh E. B., et al. , “Web-based medical image archive,” Proc. SPIE 4685, 31 (2002). 10.1117/12.467027 [DOI] [Google Scholar]

[r455] 455.Liu B. J., et al. , “PACS archive upgrade and data migration: clinical experiences,” Proc. SPIE 4685, 83 (2002). 10.1117/12.466992 [DOI] [Google Scholar]

[r456] 456.Whang T., et al. , “Financial and workflow analysis of radiology reporting processes in the planning phase of implementation of a speech recognition system,” Proc. SPIE 4685, 168 (2002). 10.1117/12.467003 [DOI] [Google Scholar]

[r457] 457.Moise A., Atkins M. S., “Workflow oriented hanging protocols for radiology workstation,” Proc. SPIE 4685, 189 (2002). 10.1117/12.467006 [DOI] [Google Scholar]

[r458] 458.Kuzmak P. M., Dayhoff R. E., “Extending DICOM imaging to new clinical specialties in the healthcare enterprise,” Proc. SPIE 4685, 233 (2002). 10.1117/12.467012 [DOI] [Google Scholar]

[r459] 459.Park H. J., et al. , “IHE Year 3 demonstration participation at RSNA 2001: image manager, image archive and MPPS manager,” Proc. SPIE 4685, 398 (2002). 10.1117/12.467033 [DOI] [Google Scholar]

[r460] 460.Ha D. H., et al. , “Effectiveness of wireless communication using 100Mbps infrared in PACS,” Proc. SPIE 4685, 391 (2002). 10.1117/12.467032 [DOI] [Google Scholar]

[r461] 461.Eichelberg M., et al. , “IHE Europe: extending the IHE initiative to the European healthcare market,” Proc. SPIE 5033, 1 (2003). 10.1117/12.480660 [DOI] [Google Scholar]

[r462] 462.Nagy P. G., Warnock M., Evans D., “Predicting PACS loading and performance metrics using Monte Carlo and queuing methods,” Proc. SPIE 5033, 48 (2003). 10.1117/12.480469 [DOI] [Google Scholar]

[r463] 463.Chan L. W. C., et al. , “International Internet2 connectivity requirements for tele-imaging consultation,” Proc. SPIE 5033, 172 (2003). 10.1117/12.481941 [DOI] [Google Scholar]

[r464] 464.Slik S., Montour M., Altman T., “Comprehensive security framework for the communication and storage of medical images,” Proc. SPIE 5033, 212 (2003). 10.1117/12.480475 [DOI] [Google Scholar]

[r465] 465.Horii S. C., “DIOM image viewers: a survey,” Proc. SPIE 5033, 251 (2003). 10.1117/12.487803 [DOI] [Google Scholar]

[r466] 466.Long L. R., et al. , “Biomedical information from a national collection of spine X-rays: film to content-based retrieval,” Proc. SPIE 5033, 70 (2003). 10.1117/12.487798 [DOI] [Google Scholar]

[r467] 467.Pavlopoulou C., Kak A. C., Brodley C. E., “Content-based image retrieval for medical imagery,” Proc. SPIE 5033, 85 (2003). 10.1117/12.487802 [DOI] [Google Scholar]

[r468] 468.Ghebreab S., Jaffe C., Smeulders A. W. M., “Concept-based retrieval of biomedical images,” Proc. SPIE 5033, 97 (2003). 10.1117/12.487796 [DOI] [Google Scholar]

[r469] 469.Nagaraj N., et al. , “Region of interest and windowing-based progressive medical image delivery using JPEG2000,” Proc. SPIE 5033, 382 (2003). 10.1117/12.480467 [DOI] [Google Scholar]

[r470] 470.Lee J., Kim H. J., Yoo H. S., “Development of effective compression for CT series,” Proc. SPIE 5033, 424 (2003). 10.1117/12.480657 [DOI] [Google Scholar]

[r471] 471.Shen S. Z., et al. , “PACS archive server database structure enabling flexible queries,” Proc. SPIE 5033, 370 (2003). 10.1117/12.480461 [DOI] [Google Scholar]

[r472] 472.Mongkolwat P., et al. , “Pathology tickler: an HL7 monitoring system to provide clinical feedback,” Proc. SPIE 5033, 281 (2003). 10.1117/12.480671 [DOI] [Google Scholar]

[r473] 473.Andriole K. P., et al. , “Transforming the radiological interpretation process: the SCAR TRIP initiative,” Proc. SPIE 5371, 1 (2004). 10.1117/12.543741 [DOI] [Google Scholar]

[r474] 474.O’Donnell K., “Update on the IHE initiative,” Proc. SPIE 5371, 52 (2004). 10.1117/12.543744 [DOI] [Google Scholar]

[r475] 475.Eichelberg M., et al. , “Ten years of medical imaging standardization and prototypical implementation; the DICOM standard and the OFFIS DICOM Toolkit (DCMTK),” Proc. SPIE 5371, 57 (2004). 10.1117/12.534853 [DOI] [Google Scholar]

[r476] 476.Samei E., Wright S. L., “Effect of viewing angle response on DICOM compliance of liquid crystal displays,” Proc. SPIE 5371, 170 (2004). 10.1117/12.536198 [DOI] [Google Scholar]

[r477] 477.Krishnan K., et al. , “Compression/decompression strategies for large-volume medical imagery,” Proc. SPIE 5371, 152 (2004). 10.1117/12.535650 [DOI] [Google Scholar]

[r478] 478.Zhou G., et al. , “Content-based cell pathology image retrieval by combining different features,” Proc. SPIE 5371, 326 (2004). 10.1117/12.532926 [DOI] [Google Scholar]

[r479] 479.Dos Santos M., Furuie S. S., “High-performance web viewer for cardiac images,” Proc. SPIE 5371, 391 (2004). 10.1117/12.535838 [DOI] [Google Scholar]

[r480] 480.Moise A., Atkins M. S., “Interaction techniques for radiology workstations: impact on users’ productivity,” Proc. SPIE 5371, 16 (2004). 10.1117/12.534468 [DOI] [Google Scholar]

[r481] 481.Sappington R. W., “Adoption and resistance: reflections on human, organizational and information technologies in PACS,” Proc. SPIE 5748, 1 (2005). 10.1117/12.596042 [DOI] [Google Scholar]

[r482] 482.Martinex-Martinez A., et al. , “A strategy for PACS development using introductory team software process,” Proc. SPIE 5748, 10 (2005). 10.1117/12.596088 [DOI] [Google Scholar]

[r483] 483.Ratib O., et al. , “Navigating the fifth dimension: new concepts in interactive multimodality and multidimensional image navigation,” Proc. SPIE 5748, 28 (2005). 10.1117/12.594648 [DOI] [Google Scholar]

[r484] 484.Lee K. H., et al. , “Managing the CT data explosion: initial experience of archiving volumetric datasets in a mini-PACS,” Proc. SPIE 5748, 427 (2005). 10.1117/12.593549 [DOI] [PMC free article] [PubMed] [Google Scholar]

[r485] 485.Lou H., Hao W., Cornelius C., “Automatic hanging protocol for chest radiographs,” Proc. SPIE 5748, 33 (2005). 10.1117/12.595419 [DOI] [PubMed] [Google Scholar]

[r486] 486.Kurup P. K., et al. , “Automatic classification of computed tomography slices into anatomic regions,” Proc. SPIE 5748, 43 (2005). 10.1117/12.595399 [DOI] [Google Scholar]

[r487] 487.Mun S. K., Cleary K., “The operating room of the future: review of OR 2020 workshop,” Proc. SPIE 5748, 73 (2005). 10.1117/12.604719 [DOI] [Google Scholar]

[r488] 488.Lemke H. U., Ratib O. M., Horii S. C., “Workflow in the operating room: review of Arrowhead 2004 seminar on imaging and informatics,” Proc. SPIE 5748, 83 (2005). 10.1117/12.606113 [DOI] [Google Scholar]

[r489] 489.Siddiqui K. M., et al. , “Correlation of radiologists’ image quality perception with quantitative assessment parameters: just-noticeable difference versus peak signal-to-noise ratios,” Proc. SPIE 5748, 58 (2005). 10.1117/12.596140 [DOI] [Google Scholar]

[r490] 490.Ogden K. M., et al. , “Quantifying the effect of monitor display settings on observer performance,” Proc. SPIE 5748, 455 (2005). 10.1117/12.594626 [DOI] [Google Scholar]

[r491] 491.Siegel E. L., et al. , “Compression of multi-slice CT: 2D versus 3D JPEG2000 and effects of slice thickness,” Proc. SPIE 5748, 162 (2005). 10.1117/12.596037 [DOI] [Google Scholar]

[r492] 492.Siddiqui K. M., et al. , “Discrete cosine transform JPEG compression versus 2D JPEG2000 compression: INDmetrix visual discrimination model image quality analysis,” Proc. SPIE 5748, 202 (2005). 10.1117/12.596146 [DOI] [Google Scholar]

[r493] 493.Rosset A., Ratib A. M., “New GRID-computing platforms for high performance multi-dimensional and multi-modality image rendering,” Proc. SPIE 5748, 218 (2005). 10.1117/12.594221 [DOI] [Google Scholar]

[r494] 494.Reddy Mogatala H. V., Gallet J., “Secure thin client architecture for DICOM image analysis,” Proc. SPIE 5748, 357 (2005). 10.1117/12.595985 [DOI] [Google Scholar]

[r495] 495.Chen X., et al. , “Evaluation of security algorithms used for security processing on DICOM images,” Proc. SPIE 5748, 539 (2005). 10.1117/12.596525 [DOI] [Google Scholar]

[r496] 496.Chawla A. S., Samei E., “A method for reduction of eye fatigue by optimizing the ambient light conditions in radiology reading rooms,” Proc. SPIE 6145, 614503 (2006). 10.1117/12.655688 [DOI] [Google Scholar]

[r497] 497.Joshi R. L., “On-demand rendering of an oblique slice through 3D volumetric data using KPEG2000 client-server framework,” Proc. SPIE 6145, 614508 (2006). 10.1117/12.653523 [DOI] [Google Scholar]

[r498] 498.Ratib O., et al. , “Hierarchical storage of large volume of multidetector CT data using distributed servers,” Proc. SPIE 6145, 61450W (2006). 10.1117/12.654616 [DOI] [Google Scholar]

[r499] 499.Horii S. C., et al. , “Impact of volumetric ultrasound on PACS,” Proc. SPIE 6145, 614512 (2006). 10.1117/12.657135 [DOI] [Google Scholar]

[r500] 500.Lehmann T. M., Abel J., Weiss C., “The impact of lossless image compression to radiographs,” Proc. SPIE 6145, 614516 (2006). 10.1117/12.651697 [DOI] [Google Scholar]

[r501] 501.Siddoway D., et al. , “Workflow in interventional radiology: nerve blocks and facet blocks,” Proc. SPIE 6145, 61450B (2006). 10.1117/12.654482 [DOI] [Google Scholar]

PERMALINK

SPIE Medical Imaging 50th anniversary: history of the Picture Archiving and Communication Systems Conference

Katherine P Andriole

Abstract.

1. Introduction

Table 1.

2. 1980’s PACS Conferences

2.1. 1981

Fig. 1.

2.2. 1982

2.3. 1983

2.4. 1984

2.5. 1985

2.6. 1986

2.7. 1987

2.8. 1988

2.9. 1989

3. 1990s PACS Conferences

3.1. 1990

3.2. 1991

3.3. 1992

3.4. 1993

3.5. 1994

3.6. 1995

3.7. 1996

3.8. 1997

3.9. 1998

3.10. 1999

Fig. 2.

4. 2000s PACS Conferences

4.1. 2000

4.2. 2001

4.3. 2002

4.4. 2003

4.5. 2004

4.6. 2005

4.7. 2006

4.8. 2007

4.9. 2008

Fig. 3.

4.10. 2009

5. 2010s PACS Conferences

5.1. 2010

5.2. 2011

5.3. 2012

5.4. 2013

5.5. 2014

5.6. 2015

5.7. 2016

5.8. 2017

5.9. 2018

5.10. 2019

6. 2020s PACS Conferences

6.1. 2020

6.2. 2021

6.3. 2022

7. Conclusion

Acknowledgments

Biography

Disclosures

References

ACTIONS

PERMALINK

RESOURCES

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